PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER :2 6: 50 AM PMC-1970624 Th ur sd ay ,0 COMET 2A ug us t, 20 07 01 PM4351 DATA SHEET ISSUE11: NOVEMBER 2005 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on COMBINED E1/T1 TRANSCEIVER/FRAMER PROPRIETARY AND CONFIDENTIAL 1 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 :2 6: CONTENTS 01 FEATURES .............................................................................................23 Receiver section:..........................................................................24 1.2 Transmitter section:......................................................................26 20 07 1.1 t, 1 APPLICATIONS ......................................................................................28 3 REFERENCES .......................................................................................29 4 APPLICATION EXAMPLE ......................................................................33 5 BLOCK DIAGRAM ..................................................................................35 6 DESCRIPTION .......................................................................................36 7 PIN DIAGRAMs ......................................................................................39 8 PIN DESCRIPTION ................................................................................41 9 FUNCTIONAL DESCRIPTION................................................................54 Receive Interface .........................................................................54 9.2 Clock and Data Recovery (CDRC)...............................................57 9.3 T1 Framer ....................................................................................60 9.4 E1 Framer ....................................................................................61 9.5 T1 Inband Loopback Code Detector (IBCD) ................................69 9.6 T1 Pulse Density Violation Detector (PDVD)................................69 Performance Monitor Counters (PMON) ......................................69 ab do u ra s ha d of bn 9.1 by ha cir o on Th ur sd ay ,0 2A ug us 2 Do wn l oa d ed 9.7 9.8 T1 Bit Oriented Code Detector (RBOC) .......................................70 9.9 HDLC Receiver (RDLC) ...............................................................70 9.10 T1 Alarm Integrator (ALMI)...........................................................71 9.11 Receive Elastic Store (RX-ELST).................................................72 PROPRIETARY AND CONFIDENTIAL 2 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Receive Jitter Attenuator (RJAT) ..................................................73 9.13 Signaling Extractor (SIGX) ...........................................................73 9.14 Receive Per-channel Serial Controller (RPSC) ............................74 9.15 T1 Signaling Aligner (SIGA) .........................................................74 9.16 T1 Basic Transmitter (XBAS) .......................................................74 9.17 E1 Transmitter (E1-TRAN) ...........................................................75 9.18 Transmit Elastic Store (TX-ELST) ................................................75 9.19 Transmit Per-Channel Serial Controller (TPSC)...........................76 9.20 T1 Inband Loopback Code Generator (XIBC) ..............................77 9.21 T1 Bit Oriented Code Generator (XBOC).....................................77 9.22 HDLC Transmitters.......................................................................77 9.23 T1 Automatic Performance Report Generation ............................78 9.24 Pulse Density Enforcer (XPDE)....................................................79 9.25 Pseudo Random Pattern Generation and Detection ....................79 9.26 Transmit Jitter Attenuator (TJAT) .................................................80 9.27 Timing Options (TOPS) ................................................................85 9.28 Line Transmitter ...........................................................................85 ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 9.12 Backplane Receive Interface (BRIF) ............................................86 9.30 Backplane Transmit Interface (BTIF)............................................87 by 9.29 JTAG Test Access Port.................................................................88 9.32 Microprocessor Interface (MPIF)..................................................88 oa d ed 9.31 Do wn l 10 11 REGISTER DESCRIPTION ....................................................................89 10.1 Normal Mode Register Memory Map ...........................................89 NORMAL MODE REGISTER DESCRIPTION ........................................98 PROPRIETARY AND CONFIDENTIAL 3 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Test Mode 0 ...............................................................................376 12.2 JTAG Test Port ...........................................................................378 :2 6: 12.1 FUNCTIONAL TIMING..........................................................................381 Transmit Backplane Interface.....................................................381 13.2 Receive Backplane Interface......................................................387 ug us t, 13.1 2A OPERATION .........................................................................................392 Configuring the COMET from Reset ..........................................392 14.2 Using the Internal HDLC Transmitters........................................398 ay ,0 14.1 sd 14 20 07 13 50 TEST FEATURES DESCRIPTION........................................................374 01 12 Th ur 14.2.1 Automatic transmission mode using interrupts: ...............399 on 14.2.2 TDPR Interrupt Routine: ..................................................400 cir o 14.2.3 Automatic transmission mode using polling:....................401 Using the Internal HDLC Receivers ...........................................402 14.4 T1 Automatic Performance Report Format.................................404 14.5 Using the Transmit Line Pulse Generator ..................................406 14.6 Using the Line Receiver .............................................................426 ra s ha d of bn ha 14.3 ab do u 14.6.1 T1 Performance Monitor Mode........................................437 14.7 Using the Test Pattern Generator...............................................439 by 14.7.1 Common Test Patterns ....................................................440 Do wn l oa d ed 14.8 Using the Loopback Modes........................................................443 14.8.1 Line Loopback .................................................................443 14.8.2 Payload Loopback ...........................................................444 14.8.3 Diagnostic Digital Loopback ............................................444 14.8.4 Per-Channel Loopback....................................................445 PROPRIETARY AND CONFIDENTIAL 4 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Using the Per-Channel Serial Controllers ..................................446 50 14.9 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 14.9.1 Initialization......................................................................446 01 14.9.2 Direct Access Mode.........................................................446 20 07 14.9.3 Indirect Access Mode ......................................................446 us t, 14.10 Isolating an Interrupt ..................................................................447 ug 14.11 Using the Performance Monitor Counter Values ........................447 2A 14.12 JTAG Support.............................................................................453 ABSOLUTE MAXIMUM RATINGS........................................................463 16 D.C. CHARACTERISTICS....................................................................464 17 A.C. TIMING CHARACTERISTICS.......................................................467 Th ur sd ay ,0 15 Microprocessor Interface Timing Characteristics........................467 17.2 Transmit Backplane Interface (Figure 57, Figure 58) .................471 17.3 Receive Backplane Interface (Figure 59, Figure 60) ..................473 17.4 Receive Digital Interface (Figure 61)..........................................477 17.5 Transmit Digital Interface (Figure 62) .........................................478 17.6 JTAG Port Interface (Figure 63) .................................................480 ra s ha d of bn ha cir o on 17.1 ORDERING AND THERMAL INFORMATION.......................................483 19 MECHANICAL INFORMATION.............................................................484 Do wn l oa d ed by ab do u 18 PROPRIETARY AND CONFIDENTIAL 5 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 :2 6: LIST OF REGISTERS 01 Register 000H: Global Configuration .................................................................99 07 Register 001H: Clock Monitor..........................................................................101 t, 20 Register 002H: Receive Options .....................................................................103 ug us Register 003H: Receive Line Interface Configuration......................................105 2A Register 004H: Transmit Line Interface Configuration .....................................108 ,0 Register 005H: Transmit Framing and Bypass Options ................................... 110 sd ay Register 006H: Transmit Timing Options ......................................................... 113 Th ur Register 007H: Interrupt Source #1 ................................................................. 118 on Register 008H: Interrupt Source #2 ................................................................. 119 cir o Register 009H: Interrupt Source #3 .................................................................120 ha Register 00AH: Master Diagnostics.................................................................121 bn Register 00BH: Master Test.............................................................................124 of Register 00CH: Analog Diagnostics.................................................................126 ha d Register 00DH: Revision/Chip ID/Global PMON Update .................................127 ra s Register 00EH: Reset......................................................................................128 ab do u Register 00FH: PRGD Positioning/Control and HDLC Control ........................129 by Register 010H: CDRC Configuration ...............................................................132 ed Register 011H: CDRC Interrupt Control...........................................................134 oa d Register 012H: CDRC Interrupt Status ............................................................135 Do wn l Register 013H: Alternate Loss of Signal Status ...............................................137 Register 014H: RJAT Interrupt Status..............................................................138 Register 015H: RJAT Divider N1 Control.........................................................139 PROPRIETARY AND CONFIDENTIAL 6 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Register 016H: RJAT Divider N2 Control.........................................................140 :2 6: Register 017H: RJAT Configuration.................................................................142 01 Register 018H: TJAT Interrupt Status ..............................................................144 20 07 Register 019H: TJAT Jitter Attenuator Divider N1 Control ...............................145 us t, Register 01AH: TJAT Divider N2 Control .........................................................146 ug Register 01BH: TJAT Configuration.................................................................148 2A Register 01CH: RX-ELST Configuration..........................................................150 ay ,0 Register 01DH: RX-ELST Interrupt Enable/Status...........................................151 sd Register 01EH: RX-ELST Idle Code ................................................................152 Th ur Register 020H: TX-ELST Configuration...........................................................153 on Register 021H: TX-ELST Interrupt Enable/Status............................................154 cir o Register 028H: RXCE Receive Data Link 1 Control ........................................155 ha Register 029H: RXCE Receive Data Link 1 Bit Select.....................................157 bn Register 02AH: RXCE Receive Data Link 2 Control ........................................158 d of Register 02BH: RXCE Receive Data Link 2 Bit Select ....................................159 ra s ha Register 02CH: RXCE Receive Data Link 3 Control........................................160 ab do u Register 02DH: RXCE Receive Data Link 3 Bit Select ....................................161 Register 030H: BRIF Configuration .................................................................162 by Register 031H: BRIF Frame Pulse Configuration ............................................165 ed Register 032H: BRIF Parity/F-bit Configuration ...............................................169 oa d Register 033H: BRIF Time Slot Offset .............................................................171 Do wn l Register 034H: BRIF Bit Offset........................................................................172 Register 038H: TXCI Transmit Data Link 1 Control .........................................174 Register 039H: TXCI Transmit Data Link 1 Bit Select......................................176 PROPRIETARY AND CONFIDENTIAL 7 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Register 03AH: TXCI Transmit Data Link 2 Control .........................................177 :2 6: Register 03BH: TXCI Transmit Data Link 2 Bit Select .....................................178 01 Register 03CH: TXCI Transmit Data Link 3 Control.........................................179 20 07 Register 03DH: TXCI Transmit Data Link 3 Bit Select .....................................180 us t, Register 040H: BTIF Configuration..................................................................181 ug Register 041H: BTIF Frame Pulse Configuration ............................................184 2A Register 042H: BTIF Parity Configuration and Status......................................186 ay ,0 Register 043H: BTIF Time Slot Offset .............................................................188 sd Register 044H: BTIF Bit Offset ........................................................................189 Th ur Register 048H: T1 FRMR Configuration ..........................................................191 on Register 049H: T1 FRMR Interrupt Enable......................................................193 cir o Register 04AH: T1 FRMR Interrupt Status.......................................................195 ha Register 04CH: IBCD Configuration ................................................................197 bn Register 04DH: IBCD Interrupt Enable/Status .................................................198 d of Register 04EH: IBCD Activate Code................................................................200 ra s ha Register 04FH: IBCD Deactivate Code ...........................................................201 ab do u Register 050H: SIGX Configuration Register (COSS = 0) ..............................202 Register 050H: SIGX Change of Signaling State Register (COSS = 1) ...........204 by Register 051H: SIGX Timeslot Indirect Status (COSS = 0).............................205 ed Register 051H: SIGX Change Of Signaling State Change (COSS=1) .............206 oa d Register 052H: SIGX Timeslot Indirect Address/Control (COSS = 0) ..............207 Do wn l Register 052H: SIGX Change of Signaling State Register (COSS = 1) ...........208 Register 053H: SIGX Timeslot Indirect Data Buffer (COSS = 0)......................209 Register 053H: SIGX Change of Signaling State (COSS = 1) .........................210 PROPRIETARY AND CONFIDENTIAL 8 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Register 054H: T1 XBAS Configuration...........................................................216 :2 6: Register 055H: T1 XBAS Alarm Transmit ........................................................218 01 Register 056H: T1 XIBC Control......................................................................219 20 07 Register 057H: T1 XIBC Loopback Code ........................................................221 us t, Register 058H: PMON Interrupt Enable/Status................................................222 ug Register 059H: PMON Framing Bit Error Count ..............................................224 2A Register 05AH: PMON OOF/COFA/Far End Block Error Count LSB ..............225 ay ,0 Register 05BH: PMON OOF/COFA/Far End Block Error Count MSB .............226 sd Register 05CH: PMON Bit Error/CRC Error Count LSB ..................................227 Th ur Register 05DH: PMON Bit Error/CRC Error Count MSB .................................228 on Register 05EH: PMON LCV Count (LSB) ........................................................229 cir o Register 05FH: PMON LCV Count (MSB) .......................................................230 ha Register 060H: T1 ALMI Configuration ............................................................231 bn Register 061H: T1 ALMI Interrupt Enable ........................................................233 d of Register 062H: T1 ALMI Interrupt Status .........................................................234 ra s ha Register 063H: T1 ALMI Alarm Detection Status .............................................235 ab do u Register 065H: T1 PDVD Interrupt Enable/Status ...........................................237 Register 067H: T1 XBOC Code.......................................................................239 by Register 069H: T1 XPDE Interrupt Enable/Status ...........................................240 ed Register 06AH: T1 RBOC Enable....................................................................242 oa d Register 06BH: T1 RBOC Code Status ...........................................................243 Do wn l Register 06CH: TPSC Configuration ...............................................................244 Register 06DH: TPSC P Access Status .........................................................245 Register 06EH: TPSC Channel Indirect Address/Control ................................246 PROPRIETARY AND CONFIDENTIAL 9 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Register 06FH: TPSC Channel Indirect Data Buffer ........................................247 :2 6: Register 070H: RPSC Configuration ...............................................................256 01 Register 071H: RPSC P Access Status .........................................................257 20 07 Register 072H: RPSC Channel Indirect Address/Control ................................258 us t, Register 073H: RPSC Channel Indirect Data Buffer........................................259 ug Register 078H: T1 APRM Configuration/Control..............................................264 2A Register 079H: T1 APRM Manual Load...........................................................266 ay ,0 Register 07AH: T1 APRM Interrupt Status.......................................................267 sd Register 07BH: T1 APRM One Second Content Octet 2 .................................268 Th ur Register 07CH: T1 APRM One Second Content Octet 3 .................................269 on Register 07DH: T1 APRM One Second Content Octet 4 .................................270 cir o Register 07EH: T1 APRM One Second Content MSB (Octet 5) ......................271 ha Register 07FH: T1 APRM One Second Content LSB (Octet 6) ......................273 bn Register 080H: E1 TRAN Configuration ..........................................................275 d of Register 081H: E1 TRAN Transmit Alarm/Diagnostic Control..........................278 ra s ha Register 082H: E1 TRAN International/National Control .................................280 ab do u Register 083H: E1 TRAN Extra Bits Control....................................................281 Register 084H: E1 TRAN Interrupt Enable ......................................................282 by Register 085H: E1 TRAN Interrupt Status .......................................................284 ed Register 086H: E1 TRAN National Bits Codeword Select ...............................286 oa d Register 087H: E1 TRAN National Bits Codeword ..........................................288 Do wn l Register 090H: E1 FRMR Frame Alignment Options.......................................290 Register 091H: E1 FRMR Maintenance Mode Options ...................................292 Register 092H: E1 FRMR Framing Status Interrupt Enable.............................294 PROPRIETARY AND CONFIDENTIAL 10 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Register 093H: E1 FRMR Maintenance/Alarm Status Interrupt Enable...........295 :2 6: Register 094H: E1 FRMR Framing Status Interrupt Indication ........................296 01 Register 095H: E1 FRMR Maintenance/Alarm Status Interrupt Indication.......297 20 07 Register 096H: E1 FRMR Framing Status .......................................................298 us t, Register 097H: E1 FRMR Maintenance/Alarm Status .....................................300 ug Register 098H: E1 FRMR Timeslot 0 International/National Bits .....................302 2A Register 099H: E1 FRMR CRC Error Counter - LSB.......................................304 ay ,0 Register 09AH: E1 FRMR CRC Error Counter - MSB/Timeslot 16 Extra Bits .305 sd Register 09BH: E1 FRMR National Bit Codeword Interrupt Enables...............308 Th ur Register 09CH: E1 FRMR National Bit Codeword Interrupts...........................310 on Register 09DH: E1 FRMR National Bit Codeword........................................... 311 cir o Register 09EH: E1 FRMR Frame Pulse/Alarm/V5.2 Link ID Interrupt Enables312 ha Register 09FH: E1 FRMR Frame Pulse/Alarm Interrupts ................................314 bn Register 0A8H (#1), 0B0H (#2), 0B8H (#3): TDPR Configuration ...................316 d of Register 0A9H (#1), 0B1H (#2), 0B9H (#3): TDPR Upper Transmit Threshold318 ra s ha Register 0AAH (#1), 0B2H (#2), 0BAH (#3): TDPR Lower Interrupt Threshold319 ab do u Register 0ABH (#1), 0B3H (#2), 0BBH (#3): TDPR Interrupt Enable ..............320 Register 0ACH (#1), 0B4H (#2), 0BCH (#3): TDPR Interrupt Status ...............321 by Register 0ADH (#1), 0B5H (#2), 0BDH (#3): TDPR Transmit Data .................323 ed Registers 0C0H (#1), 0C8H (#2), 0D0H (#3): RDLC Configuration .................324 oa d Registers 0C1H (#1), 0C9H (#2), 0D1H (#3): RDLC Interrupt Control ............326 Do wn l Registers 0C2H (#1), 0CAH (#2), 0D2H (#3): RDLC Status ............................327 Registers 0C3H (#1), 0CBH (#2), 0D3H (#3): RDLC Data ..............................330 Registers 0C4H (#1), 0CCH (#2), 0D4H (#3): RDLC Primary Address Match.331 PROPRIETARY AND CONFIDENTIAL 11 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 Registers 0C5H (#1), 0CDH (#2), 0D5H (#3): RDLC Secondary Address Match ..............................................................................................................332 01 :2 Register 0D6H: CSU Configuration .................................................................333 07 Register 0D8H: RLPS Equalization Indirect Data ............................................335 20 Register 0D9H: RLPS Equalization Indirect Data ............................................336 us t, Register 0DAH: RLPS Equalization Indirect Data............................................337 2A ug Register 0DBH: RLPS Equalization Indirect Data............................................338 ,0 Register 0DCH: RLPS Equalizer Voltage Reference .......................................339 sd ay Register 0E0H: PRGD Control ........................................................................340 ur Register 0E1H: PRGD Interrupt Enable/Status................................................342 on Th Register 0E2H: PRGD Shift Register Length...................................................344 o Register 0E3H: PRGD Tap ..............................................................................345 cir Register 0E4H: PRGD Error Insertion .............................................................346 bn ha Register 0E8H: PRGD Pattern Insertion #1.....................................................347 of Register 0E9H: PRGD Pattern Insertion #2.....................................................348 ha d Register 0EAH: PRGD Pattern Insertion #3 ....................................................349 ra s Register 0EBH: PRGD Pattern Insertion #4 ....................................................350 ab do u Register 0ECH: PRGD Pattern Detector #1 ....................................................351 Register 0EDH: PRGD Pattern Detector #2 ....................................................352 by Register 0EEH: PRGD Pattern Detector #3 ....................................................353 oa d ed Register 0EFH: PRGD Pattern Detector #4.....................................................354 wn l Register 0F0H: XLPG Line Driver Configuration .............................................355 Do Register 0F1H: XLPG Control/Status ..............................................................357 Register 0F2H: XLPG Pulse Waveform Storage Write Address ......................358 PROPRIETARY AND CONFIDENTIAL 12 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Register 0F3H: XLPG Pulse Waveform Storage Data .....................................359 :2 6: Register 0F4H: XLPG Analog Test Negative Control .......................................360 01 Register 0F5H: XLPG Analog Test Positive Control ........................................361 20 07 Register 0F6H: XLPG Fuse Data Select..........................................................362 us t, Register 0F8H: RLPS Configuration and Status ..............................................363 ug Register 0F9H: RLPS ALOS Detection/Clearance Threshold..........................365 2A Register 0FAH: RLPS ALOS Detection Period ................................................367 ay ,0 Register 0FBH: RLPS ALOS Clearance Period...............................................368 sd Register 0FCH: RLPS Equalization Indirect Address ......................................369 Th ur Register 0FDH: RLPS Equalization Read/WriteB Select .................................370 on Register 0FEH: RLPS Equalizer Loop Status and Control...............................371 cir o Register 0FFH: RLPS Equalizer Configuration................................................372 Do wn l oa d ed by ab do u ra s ha d of bn ha Register 00BH: COMET Master Test ...............................................................375 PROPRIETARY AND CONFIDENTIAL 13 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 :2 6: LIST OF FIGURES - Wireless Base Station Application.................................................33 Figure 2 - V5.1 Interface Application .............................................................34 Figure 3 PM4351-RI COMET Pin Diagram ...................................................39 Figure 4 PM4351-NI COMET Pin Diagram ...................................................40 Figure 5 - External Analog Interface Circuits.................................................55 Figure 6 - T1 Jitter Tolerance ........................................................................59 Figure 7 - Compliance with ITU-T Specification G.823 for E1 Input Jitter......60 Figure 8 - CRC Multiframe Alignment Algorithm ...........................................65 Figure 9 - TJAT Jitter Tolerance ....................................................................82 Figure 10 - TJAT Minimum Jitter Tolerance vs. XCLK Accuracy .....................83 Figure 11 - TJAT Jitter Transfer ......................................................................84 Figure 12 - Transmit Timing Options ............................................................. 117 bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 Figure 1 of Figure 13 - Transmit Backplane: CMS=0, FE=1, DE=1, BTFP is Input............381 ha d Figure 14 - Transmit Backplane: CMS=0, FE=1, DE=0, BTFP is Input............381 ra s Figure 15 - Transmit Backplane: CMS=1, FE=1, DE=1, BTFP is Input............381 ab do u Figure 16 - Transmit Backplane: CMS=1, FE=0, DE=1, BTFP is Input...........381 by Figure 17 - Transmit Backplane: CMS=0, FE=1, DE=1, BTFP is Output.........382 Figure 19 - Transmit Backplane at 1.544 Mbit/s (T1 mode) ..........................382 Figure 20 - Transmit Backplane at 2.048 Mbit/s (T1 mode) ..........................383 Figure 21 - Transmit Backplane at 2.048 Mbit/s (E1 mode) ..........................384 Figure 22 - Transmit Backplane at 4.096 Mbit/s (T1 mode) ..........................384 Do wn l oa d ed Figure 18 - Transmit Backplane: CMS=0, FE=1, DE=0, BTFP is Output.........382 PROPRIETARY AND CONFIDENTIAL 14 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - Transmit Backplane at 4.096 Mbit/s (E1 mode) ..........................385 Figure 24 - Transmit Backplane at 8.192 Mbit/s (T1 mode) ..........................385 Figure 25 - Transmit Backplane at 8.192 Mbit/s (E1 mode) ..........................386 Figure 26 - Concentration Highway Interface Timing, Example 1 .................386 Figure 27 - Concentration Highway Interface Timing, Example 2 .................386 Figure 28 - Receive Backplane at 1.544 Mbit/s (T1 Mode) ...........................387 Figure 29 - Receive Backplane at 2.048 Mbit/s (T1 Mode) ...........................388 Figure 30 - Receive Backplane at 2.048 Mbit/s (E1 Mode)...........................388 Figure 31 - Receive Backplane at 4.096 Mbit/s (T1 Mode) ..........................389 Figure 32 - Receive Backplane at 4.096 Mbit/s (E1 Mode)..........................389 Figure 33 - Receive Backplane at 8.192 Mbit/s (T1 Mode) ..........................390 Figure 34 - Receive Backplane at 8.192 Mbit/s (E1 Mode)..........................390 Figure 35 - Concentration Highway Interface Timing, Example 1 ................391 Figure 36 - Concentration Highway Interface Timing, Example 2 ................391 Figure 37 - Typical Data Frame.....................................................................402 Figure 38 - Pattern Generator Structure .......................................................440 Figure 39 - Line Loopback ............................................................................443 - Payload Loopback ......................................................................444 Figure 41 - Diagnostic Digital Loopback .......................................................445 Figure 42 - LCV Count vs. BER (E1 mode) ..................................................449 Figure 43 - FER Count vs. BER (E1 mode) ..................................................449 Figure 44 - CRCE Count vs. BER (E1 mode) ...............................................450 Figure 45 - LCV Count vs. BER (T1 mode)...................................................451 Figure 46 - FER Count vs. BER (T1 ESF mode) ..........................................451 Do wn l oa d ed Figure 40 by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Figure 23 PROPRIETARY AND CONFIDENTIAL 15 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - CRCE Count vs. BER (T1 ESF mode)........................................452 Figure 48 - CRCE Count vs. BER (T1 SF mode) ..........................................452 Figure 49 - Boundary Scan Architecture .......................................................453 Figure 50 - TAP Controller Finite State Machine ...........................................455 Figure 51 - Input Observation Cell (IN_CELL) ..............................................460 Figure 52 - Output Cell (OUT_CELL)............................................................461 Figure 53 - Bidirectional Cell (IO_CELL).......................................................462 Figure 54 - Layout of Output Enable and Bidirectional Cells.........................462 Figure 55 - Microprocessor Read Access Timing..........................................468 Figure 56 - Microprocessor Write Access Timing ..........................................470 Figure 57 - Backplane Transmit Input Timing Diagram .................................472 Figure 58 - Backplane Transmit Output Timing Diagram ..............................473 Figure 59 - Backplane Receive Input Timing Diagram ..................................475 Figure 60 - Backplane Receive Output Timing Diagram ...............................476 Figure 61 - Digital Receive Interface Timing Diagram...................................478 Figure 62 - Digital Transmit Interface Timing Diagram ..................................479 Figure 63 - JTAG Port Interface Timing.........................................................481 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Figure 47 PROPRIETARY AND CONFIDENTIAL 16 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 :2 6: LIST OF TABLES - Backplane Transmit Interface (4 pins) ..........................................41 Table 2 - Backplane Receive Interface (4 pins) ...........................................43 Table 3 - Transmit Line Interface (6 pins) ....................................................45 Table 4 - Receive Line Interface (4 pins) .....................................................46 Table 5 - Timing Options Control (5 pins) ....................................................46 Table 6 - Analog Support Circuitry (4 pins) ..................................................47 Table 7 - JTAG (IEEE 1149.1) Boundary Scan Test Interface (5 pins).........48 Table 8 - Microprocessor Interface (23 pins) ...............................................49 Table 9 - Power and Ground (25 pins).........................................................50 Table 10 - PM4351-RI Pin Summary .............................................................52 Table 11 PM4351-NI Pin Summary ...............................................................52 Table 12 - External Component Descriptions ................................................56 Table 13 - Typical Input Return Loss at Receiver ..........................................57 Table 14 - Termination Resistors, Transformer Ratios and TRL ....................57 Table 15 - E1-FRMR Framing States.............................................................66 Table 16 - Normal Mode Register Memory Map............................................89 Table 17 - TJAT FIFO Output Clock Source ............................................... 113 - TJAT PLL Source........................................................................ 114 Table 19 - Transmit Timing Options Summary............................................. 114 Table 20 - Loss of Signal Thresholds ..........................................................133 Table 21 - Receive Backplane NXDS0 Mode Selection ..............................162 Table 22 - Receive Backplane Rate ............................................................164 Do wn l oa d Table 18 ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 Table 1 PROPRIETARY AND CONFIDENTIAL 17 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - E1 Receive Backplane Frame Pulse Configurations ..................167 Table 24 - Receive Backplane Tri-state Control...........................................170 Table 25 - Receive Backplane Bit Offset for CMS = 0 .................................173 Table 26 - Receive Backplane Bit Offset for CMS = 1 .................................173 Table 27 - Transmit Backplane NXDS0 Mode Selection..............................181 Table 28 - Transmit Backplane Rate............................................................183 Table 29 - Transmit Backplane Bit Offset for CMS = 0 ................................190 Table 30 - Transmit Backplane Bit Offset for CMS = 1 ................................190 Table 31 - T1 Framing Modes......................................................................192 Table 32 - Loopback Code Configurations ..................................................197 Table 33 - SIGX Indirect Register Map ........................................................210 on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Table 23 cir o Table 34 - SIGX Indirect Registers 10H - 1FH: Current Timeslot/Channel Signaling Data .................................................................................................212 bn ha Table 35 - SIGX Indirect Registers 20H - 3FH: Delayed Timeslot/Channel Signaling Data .................................................................................................213 - Indirect Registers 40H - 5FH: Per-Timeslot Configuration..........213 Table 37 - SIGX Per-Channel T1 Data Conditioning ...................................214 Table 38 - SIGX Per-Channel E1 Data Conditioning ...................................214 ab do u ra s ha d of Table 36 - T1 Framing Formats ...................................................................217 Table 40 - T1 Zero Code Suppression Formats...........................................217 by Table 39 - Transmit In-band Code Length ...................................................220 Table 42 - T1 Framing Modes......................................................................232 Table 43 - TPSC Indirect Register Map .......................................................247 Table 44 - TPSC Indirect Registers 20H-3FH: PCM Data Control byte .......249 Table 45 - TPSC Transmit Data Conditioning ..............................................250 Do wn l oa d ed Table 41 PROPRIETARY AND CONFIDENTIAL 18 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - Transmit Test Pattern Modes ......................................................250 Table 47 - Transmit Zero Code Suppression Formats .................................251 Table 48 - TPSC Indirect Registers 40H-5FH: IDLE Code byte...................252 Table 49 - TPSC Indirect Registers 60H-7FH: Signaling/E1 Control byte ...252 Table 50 - Transmit Per-timeslot Data Manipulation ....................................253 Table 51 - A-Law Digital Milliwatt Pattern ....................................................253 Table 52 - -Law Digital Milliwatt Pattern.....................................................254 Table 53 - RPSC Indirect Register Map.......................................................259 Table 54 - RPSC Indirect Registers 20H-3FH: PCM Data Control byte.......261 Table 55 - Receive Test Pattern Modes.......................................................261 Table 56 byte - RPSC Indirect Registers 40H-5FH: Data Trunk Conditioning Code 263 Table 57 byte - RPSC Indirect Registers 61H-7FH: Signaling Trunk Conditioning 263 Table 58 - NmNi Settings.............................................................................274 Table 59 - E1 Signaling Insertion Mode.......................................................275 Table 60 - E1 Timeslot 0 Bit 1 Insertion Control Summary ..........................277 Table 61 - National Bits Codeword Select ...................................................287 ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Table 46 - Timeslot 0 Bit Position Allocation ................................................303 Table 63 - Signaling Multiframe Timeslot 16, Frame 0 Bit Positions ............307 by Table 62 - E1 FRMR Codeword Select........................................................309 Table 65 - Receive Packet Byte Status........................................................327 Table 66 - Clock Synthesis Mode ................................................................333 Table 67 - Pattern Detector Register Configurations ...................................340 Table 68 - Error Insertion Rates ..................................................................346 Do wn l oa d ed Table 64 PROPRIETARY AND CONFIDENTIAL 19 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - Transmit Output Amplitude .........................................................356 Table 70 - ALOS Detection/Clearance Thresholds ......................................365 Table 71 - Equalization Feedback Frequencies...........................................372 Table 72 - Valid Period ................................................................................373 Table 73 - Observing Inputs in Test Mode 0 ................................................376 Table 74 - Controlling Outputs in Test Mode 0.............................................377 Table 75 - Boundary Scan Register.............................................................379 Table 76 - Default Settings ..........................................................................392 Table 77 - ESF Frame Format.....................................................................393 Table 78 - SLC(R)96 Frame Format ..............................................................394 Table 79 - SF Frame Format .......................................................................395 Table 80 - T1DM Frame Format ..................................................................395 Table 81 - E1 Frame Format .......................................................................396 Table 82 - PMON Polling Sequence ............................................................397 Table 83 - ESF FDL Processing ..................................................................398 Table 84 - Performance Report Message Structure and Contents ..............405 Table 85 - Performance Report Message Structure Notes ..........................405 ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Table 69 - Performance Report Message Contents.....................................406 Table 87 - Transmit Waveform Values for T1 Long Haul (LBO 0 dB):..........407 by Table 86 - Transmit Waveform Values for T1 Long Haul (LBO 7.5 dB):.......408 Table 89 - Transmit Waveform Values for T1 Long Haul (LBO 15 dB):........409 Table 90 - Transmit Waveform Values for T1 Long Haul (LBO 22.5 dB):.....410 Table 91 - Transmit Waveform Values for T1 Short Haul (0 - 110 ft.):.......... 411 Table 92 - Transmit Waveform Values for T1 Short Haul (110 - 220 ft.): .....412 Do wn l oa d ed Table 88 PROPRIETARY AND CONFIDENTIAL 20 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - Transmit Waveform Values for T1 Short Haul (220 - 330 ft.):.....413 Table 94 - Transmit Waveform Values for T1 Short Haul (330 - 440 ft.):.....414 Table 95 - Transmit Waveform Values for T1 Short Haul (440 - 550 ft.):.....415 Table 96 - Transmit Waveform Values for T1 Short Haul (550 - 660 ft.):.....416 Table 97 - TR62411 Transmit Waveform Values for T1 Long Haul (LBO 0 dB): 417 Table 98 - TR62411 Transmit Waveform Values for T1 Short Haul (0 - 110 ft.): 418 Table 99 220 ft.): - TR62411 Transmit Waveform Values for T1 Short Haul (110 - 419 sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Table 93 Th ur Table 100 - TR62411 Transmit Waveform Values for T1 Short Haul (220 - 330 ft.): 420 o on Table 101 - TR62411 Transmit Waveform Values for T1 Short Haul (330 - 440 ft.): 421 ha cir Table 102 - TR62411 Transmit Waveform Values for T1 Short Haul (440 - 550 ft.): 422 of bn Table 103 - TR62411 Transmit Waveform Values for T1 Short Haul (550 - 660 ft.): 423 ha d Table 104 - Transmit Waveform Values for E1 120 Ohm:..............................424 ra s Table 105 - Transmit Waveform Values for E1 75 Ohm:................................425 ab do u Table 106 - RLPS Register Programming........................................................427 Table 107 - RLPS Equalizer RAM Table (T1 mode) ......................................428 ed by Table 108 - RLPS Equalizer RAM Table (E1 mode) ......................................432 oa d Table 109 - RLPS Equalizer Lookup Table for T1 Performance Monitor Mode 437 Do wn l Table 110 - Pseudo-Random Pattern Generation (PS bit = 0) ......................440 Table 111 - Repetitive Pattern Generation (PS bit = 1) .................................442 Table 112 - PMON Counter Saturation Limits (E1 mode)..............................448 PROPRIETARY AND CONFIDENTIAL 21 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Table 113 - PMON Counter Saturation Limits (T1 mode) ..............................448 :2 6: Table 114 - Boundary Scan Register.............................................................458 01 Table 115 - D.C. Characteristics....................................................................464 20 07 Table 116 - Microprocessor Read Access (Figure 55)...................................467 us t, Table 117 - Microprocessor Write Access (Figure 56) ...................................469 ug Table 118 - Transmit Backplane Interface .....................................................471 2A Table 119 - Receive Backplane Interface ......................................................473 ay ,0 Table 120 - Receive Digital Interface.............................................................477 sd Table 121 - Transmit Digital Interface ............................................................478 Th ur Table 122 - JTAG Port Interface ....................................................................480 on Table 123 - Ordering Information...................................................................483 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o Table 124 - Thermal Information....................................................................483 PROPRIETARY AND CONFIDENTIAL 22 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER FEATURES :2 6: 1 50 AM PMC-1970624 Monolithic device which integrates software selectable full-featured T1 and E1 framers and T1 and E1 short haul and long haul line interfaces. * Meets or exceeds T1 and E1 shorthaul and longhaul network access specifications including ANSI T1.102, T1.403, T1.408, AT&T TR 62411, ITU-T G.703, G.704 as well as ETSI 300-011, CTR-4, CTR-12 and CTR-13. * Provides encoding and decoding of B8ZS, HDB3 and AMI line codes. * Provides receive equalization, clock recovery and line performance monitoring. * Provides transmit jitter attenuation and digitally programmable long haul and short haul line build out. * Provides on-board programmable binary sequence generators and detectors for error testing including support for patterns recommended in ITU-T O.151. * Provides three full-featured HDLC controllers, each with 128-byte transmit and receive FIFO buffers. * Automatically generates and transmits DS-1 performance report messages to ANSI T1.231 and ANSI T1.408 specifications. * Compatible with Mitel ST(R)-bus, AT&T CHI(R) and MVIP PCM backplanes, supporting rates of 1.544 Mbit/s, 2.048 Mbit/s, 4.096 Mbit/s, and 8.192 Mbit/s. Up to four COMET devices may be byte-interleaved on a single backplane with no external circuitry. * Supports NxDS0 fractional bandwidth backplane. * Provides an 8-bit microprocessor bus interface for configuration, control, and status monitoring. Uses line rate system clock. oa d * ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 * Provides a IEEE P1149.1 (JTAG) compliant test access port (TAP) and controller for boundary scan test. * Implemented in a low power 5 V tolerant +3.3 V CMOS technology. Do wn l * PROPRIETARY AND CONFIDENTIAL 23 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Available in a high density 80-pin MQFP (14 mm by 14 mm) package or an 81-ball CABGA (9 mm by 9 mm) package. * Provides a -40C to +85C Industrial temperature operating range. 01 :2 6: 50 * 20 07 Receiver section: * Guaranteed T1 signal reception for distances with up to 36 dB of cable attenuation under production test conditions (772 kHz, VDD = 3.069V and 25C) using PIC 22 gauge cable emulation. * Guaranteed E1 signal reception for distances with up to 36 dB of cable attenuation under production test conditions (1.024 MHz, VDD = 3.069V and 25C) using PIC 22 gauge cable emulation. * Recovers clock and data using a digital phase locked loop for high jitter tolerance. * Provides an alternative digital interface for applications without line interface units. * Frames to ITU-T G.704 basic and CRC-4 multiframe formatted E1 signals. The framing procedures are consistent ITU-T G.706 specifications. * Frames to DSX/DS-1 signals in D4, SF, ESF and SLC(R)96 formats. * Frames to TTC JT-G704 multiframe formatted J1 signals. Supports the alternate CRC-6 calculation for Japanese applications. * Frames in the presence of and detects the "Japanese Yellow" alarm. * Tolerates more than 0.3 UI peak-to-peak, high frequency jitter as required by AT&T TR 62411 and Bellcore TR-TSY-000170. * Detects violations of the ANSI T1.403 12.5% pulse density rule over a moving 192-bit window. ra s ab do u by ed Provides loss of signal detection as per ITU-T G.775 and ANSI T1.231. Red, Yellow, and AIS alarm detection and integration are according to ANSI T1.231 specifications. Do wn l oa d * ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 1.1 ISSUE 11 AM PMC-1970624 * Provides programmable in-band loopback activate and deactivate code detection. PROPRIETARY AND CONFIDENTIAL 24 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Supports line and path performance monitoring according to AT&T and ANSI specifications. Accumulators are provided for counting ESF CRC-6 errors, framing bit errors, line code violations and loss of frame or change of frame alignment events. * Provides ESF bit-oriented code detection and an HDLC/LAPD interface for terminating the ESF facility data link. * Supports polled or interrupt-driven servicing of the HDLC interface. * Extracts the data link in ESF and T1DM (DDS) modes. Optionally extracts a datalink in the E1 national use bits. * Extracts 4-bit codewords from the E1 national use bits as specified in ETS 300 233 * Extracts up to three HDLC links from arbitrary time slots to support the Dchannel for ISDN Primary Rate Interfaces and the C-channels for V5.1/V5.2 interfaces. * Detects the V5.2 link identification signal. * Provides a two-frame elastic store buffer for backplane rate adaptation that performs controlled slips and indicates slip occurrence and direction. * Provides DS-1 robbed bit signaling extraction, with optional data inversion, programmable idle code substitution, digital milliwatt code substitution, bit fixing, and two superframes of signaling debounce on a per-channel basis. * Frames to the E1 signaling multiframe alignment when enabled and extracts channel associated signaling. Alternatively, a common channel signaling data link may be extracted from timeslot 16. * Can be programmed to generate an interrupt on change of signaling state. * Provides trunk conditioning which forces programmable trouble code substitution and signaling conditioning on all channels or on selected channels. oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 * Do wn l * * Provides diagnostic, line loopbacks and per-DS0 line loopback. Provides an integral pattern detector that may be programmed to detect common pseudo-random sequences. The programmed sequence may be detected in the entire frame, or on an NxDS0 basis. PROPRIETARY AND CONFIDENTIAL 25 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Provides an integral pattern generator that may be programmed to generate common pseudo-random or repetitive sequences towards the backplane. * Provides tristateable single-rail PCM and signaling data outputs for 1.544 Mbit/s, 2.048 Mbit/s, 4.096 Mbit/s or 8.192 Mbit/s backplane buses. 07 01 :2 6: 50 * 20 Transmitter section: Supports transfer of transmitted single rail PCM and signaling data from 1.544 Mbit/s, 2.048 Mbit/s, 4.096 Mbit/s or 8.192 Mbit/s backplane buses. * Generates DSX-1 shorthaul and DS-1 longhaul pulses with programmable pulse shape compatible with AT&T, ANSI and ITU requirements. * Generates E1 pulses compliant to G.703 recommendations. * Provides a digitally programmable pulse shape extending up to 5 transmitted bit periods for custom long haul pulse shaping applications. * Provides line outputs which are current limited and may be tristated for protection or in redundant applications. * Provides an alternative digital interface for external line interface units. * Provides a digital phase locked loop for generation of a low jitter transmit clock complying with all jitter attenuation, jitter transfer and residual jitter specifications of AT&T TR 62411 and ETSI TBR 12 and TBR 13. * Provides a FIFO buffer for jitter attenuation and rate conversion in the transmit path. * Provides a two-frame payload slip buffer to allow independent backplane and line timing. * Provides an integral pattern generator that may be programmed to generate common pseudo-random or repetitive sequences. The programmed sequence may be inserted in the entire frame, or on an NxDS0 basis. on Th ur sd ay ,0 2A ug us t, * oa d ed by ab do u ra s ha d of bn ha cir o 1.2 ISSUE 11 AM PMC-1970624 Do wn l * * Provides an integral pattern detector that may be programmed to detect common pseudo-random or repetitive sequences from the backplane. Transmits G.704 basic and CRC-4 multiframe formatted E1 signals or D4, SF or ESF formatted DSX/DS-1 signals. PROPRIETARY AND CONFIDENTIAL 26 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Transmits TTC JT-G704 multiframe formatted J1 signals. Supports the alternate ESF CRC-6 calculation for Japanese applications. * Transmits the "Japanese Yellow" alarm. * Supports unframed mode and framing bit, CRC, or data link by-pass. * Provides signaling insertion, programmable idle code substitution, digital milliwatt code substitution, and data inversion on a per channel basis. * Provides trunk conditioning which forces programmable trouble code substitution and signaling conditioning on all channels or on selected channels. * Provides minimum ones density through Bell (bit 7), GTE or DDS zero code suppression on a per channel basis. * Detects violations of the ANSI T1.403 12.5% pulse density rule over a moving 192-bit window and optionally stuffs ones to maintain minimum ones density. * Allows insertion of framed or unframed in-band loopback code sequences. * Allows insertion of a data link in ESF or T1DM (DDS) DS-1 modes. Optionally inserts a datalink in the E1 national use bits. * Supports 4-bit codeword insertion in the E1 national use bits as specified in ETS 300 233 * Inserts up to three HDLC links into arbitrary time slots to support the Dchannel for ISDN Primary Rate Interfaces and the C-channels for V5.1/V5.2 interfaces. * Supports transmission of the alarm indication signal (AIS) and the Yellow alarm signal. Supports "Japanese Yellow" alarm generation. * Provides ESF bit-oriented code generation. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 * PROPRIETARY AND CONFIDENTIAL 27 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER APPLICATIONS :2 6: 2 50 AM PMC-1970624 T1/E1 Wireless Digital Loop Carriers (DLC's) and Cellular Base Stations * T1/E1 Internet Access Equipment * T1/E1 Channel Service Units (CSU) * T1/E1 Frame Relay Interfaces * T1/E1 ATM Interfaces * T1/E1 Multiplexers (CPE MUX) * Digital Private Branch Exchanges (PBX) * Digital Access Cross-Connect Systems (DACS) and Electronic DSX CrossConnect Systems (EDSX) * ISDN Primary Rate Interfaces (PRI) * Test Equipment Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 * PROPRIETARY AND CONFIDENTIAL 28 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER REFERENCES :2 6: 3 50 AM PMC-1970624 07 01 1. ANSI - T1.101-1987 - American National Standard for Telecommunications Digital Hierarchy - Timing Synchronization. t, 20 2. ANSI - T1.102-1993 - American National Standard for Telecommunications Digital Hierarchy - Electrical Interfaces. 2A ug us 3. ANSI - T1.107-1995 - American National Standard for Telecommunications Digital Hierarchy - Formats Specification. ay ,0 4. ANSI - T1.231-1993 - American National Standard for Telecommunications Layer 1 In-Service Digital Transmission Performance Monitoring ur sd 5. ANSI - T1.403-1995 - American National Standard for Telecommunications Carrier to Customer Installation - DS-1 Metallic Interface Specification. o on Th 6. ANSI - T1.408-1990 - American National Standard for Telecommunications Integrated Services Digital Network (ISDN) Primary Rate - Customer Installation Metallic Interfaces Layer 1 Specification. ha cir 7. AT&T - PUB 43802 - Digital Multiplexes Requirements and Objectives, July 1982. of bn 8. AT&T - PUB 54016 - Requirements For Interfacing Digital Terminal Equipment To Services Employing The Extended Superframe Format, October 1984. ra s ha d 9. AT&T - TR 62411 - Accunet T1.5 - Service Description and Interface Specification, December 1990. ab do u 10. AT&T - TR 62411 - Accunet T1.5 - Service Description and Interface Specification, Addendum 1, March 1991. by 11. AT&T - TR 62411 - Accunet T1.5 - Service Description and Interface Specification, Addendum 2, October 1992. oa d ed 12. AT&T - Interface Specification - Concentration Highway Interface November 1990. Do wn l 13. Bellcore - Digital Cross-Connect System Requirements and Objectives, TR-TSY-000170, Issue 1, November 1985. 14. Bellcore - Extended Superframe format (ESF),TR-TSY-000194, Issue 1, December 1987 PROPRIETARY AND CONFIDENTIAL 29 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 15. ETSI - ETS 300 011 - Integrated Services Digital Network (ISDN); Primary Rate User-Network Interface Layer 1 Specification and Test Principles, April 1992. 20 07 01 16. ETSI - ETS 300 011 A1 - Integrated Services Digital Network (ISDN); Primary Rate User-Network Interface Layer 1 Specification and Test Principles, December 1992. ug us t, 17. ETSI - ETS 300 011 A2 - Integrated Services Digital Network (ISDN); Primary Rate User-Network Interface Layer 1 Specification and Test Principles, March 1996. sd ay ,0 2A 18. ETSI - ETS 300 166 - Transmission and Multiplexing (TM); Physical and Electrical Characteristics of Hierarchical Digital Interfaces for Equipment Using the 2 048 kbit/s - based Plesiochronous or Synchronous Digital Hierarchies, August 1993. Th ur 19. ETSI - ETS 300 233 - Integrated Services Digital Network (ISDN); Access Digital Section for ISDN Primary Rate, May 1994. cir o on 20. ETSI - ETS 300 324-1 - Signaling Protocols and Switching (SPS); V interfaces at the Digital Local Exchange (LE) V5.1 Interface for the Support of Access Network (AN) Part 1: V5.1 Interface Specification, February 1994. of bn ha 21. ETSI - ETS 300 347-1 - Signaling Protocols and Switching (SPS); V Interfaces at the Digital Local Exchange (LE) V5.2 Interface for the Support of Access Network (AN) Part 1: V5.2 Interface Specification, September 1994. ra s ha d 22. ETSI - CTR 4 - Integrated Services Digital Network (ISDN); Attachment requirements for terminal equipment to connect to an ISDN using ISDN primary rate access, November 1995. by ab do u 23. ETSI - CTR 12 - Business Telecommunications (BT); Open Network Provision (ONP) technical requirements; 2 048 kbit/s digital unstructured leased lines (D2048U) Attachment requirements for terminal equipment interface, December 1993. oa d ed 24. ETSI - CTR 13 - Business Telecommunications (BTC); 2 048 kbit/s digital structured leased lines (D2048S); Attachment requirements for terminal equipment interface, January 1996. Do wn l 25. FCC Rules - Part 68.308 - Signal Power Limitations 26. ITU-T - Recommendation G.703 - Physical/Electrical Characteristics of Hierarchical Digital Interface, Geneva, 1991. PROPRIETARY AND CONFIDENTIAL 30 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 27. ITU-T - Recommendation G.704 - Synchronous Frame Structures Used at Primary Hierarchical Levels, July 1995. 01 :2 28. ITU-T - Recommendation G.706 - Frame Alignment and CRC Procedures Relating to G.704 Frame Structures, 1991. t, 20 07 29. ITU-T - Recommendation G.732 - Characteristics of Primary PCM Multiplex Equipment Operating at 2048 kbit/s, 1993. ug us 30. ITU-T - Recommendation G.711 - Pulse Code Modulation (PCM) of Voice Frequencies, 1993. 2A 31. ITU-T - Recommendation G.775 - Loss of Signal (LOS), November 1994. sd ay ,0 32. ITU-T Recommendation G.802, - Interworking Between Networks Based on Different Digital Hierarchies and Speech Encoding Laws, 1993. Th ur 33. ITU-T Recommendation G.823, - The Control of Jitter and Wander Within Digital Networks Which are Based on the 2048 kbit/s Hierarchy, 1993. cir o on 34. ITU-T Recommendation G.964, - V-Interfaces at the Digital Local Exchange (LE) - V5.1 Interface (Based on 2048 kbit/s) for the Support of Access Network (AN), June 1994. of bn ha 35. ITU-T Recommendation G.965, - V-Interfaces at the Digital Local Exchange (LE) - V5.2 Interface (Based on 2048 kbit/s) for the Support of Access Network (AN), March 1995. ha d 36. ITU-T - Recommendation I.431 - Primary Rate User-Network Interface - Layer 1 Specification, 1993. ab do u ra s 37. ITU-T Recommendation O.151, - Error Performance Measuring Equipment For Digital Systems at the Primary Bit Rate and Above, 1988. by 38. ITU-T Recommendation O.152 - Error Performance Measuring Equipment for Bit Rates of 64 kbit/s and N X 64 kbit/s, October 1992 oa d ed 39. ITU-T Recommendation O.153 - Basic Parameters for the Measurement of Error Performance at Bit Rates below the Primary Rate, October 1992. Do wn l 40. TTC Standard JT-G703 - Physical/Electrical Characteristics of Hierarchical Digital Interfaces, 1995. 41. TTC Standard JT-G704 - Frame Structures on Primary and Secondary Hierarchical Digital Interfaces, 1995. PROPRIETARY AND CONFIDENTIAL 31 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 42. TTC Standard JT-G706 - Frame Synchronization and CRC Procedure 01 :2 6: 43. TTC Standard JT-I431 - ISDN Primary Rate User-Network Interface Layer 1 Specification, 1995. 20 07 44. Nippon Telegraph and Telephone Corporation - Technical Reference for HighSpeed Digital Leased Circuit Services, Third Edition, 1990. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 45. GO-MVIP - Multi-Vendor Integration Protocol, MVIP-90 Release 1.1, 1994. PROPRIETARY AND CONFIDENTIAL 32 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER APPLICATION EXAMPLE 07 20 Tx/Rx RF Subsystem us PM4351 COMET TOCTL/TQUAD/ QDSX EQUAD T1/E1/J1 Longhaul/ Shorthaul LIU TOCTL/TQUAD/ QDSX EQUAD Software Selectable T1/E1/J1 Framer MVIP Intel or Motorola P Low Power 3.3v Power Supply ,0 PM4351 COMET ay TOCTL/TQUAD/ QDSX EQUAD CDMA/TDMA/GSM sd Base Transceiver Station Th ur Base Station Controller DS3 or Fibre Optics MVIP ug Basestation Switch Fabric PM8313 D3MX or PM5342 SPECTRA Software Selectable T1/E1/J1 Framer t, T1/E1/J1 Longhaul/ Shorthaul LIU TOCTL/TQUAD/ QDSX EQUAD 01 - Wireless Base Station Application 2A Figure 1 :2 6: 4 50 AM PMC-1970624 o on COMET provides a complete physical layer solution for Basestation designs, while the PM4314 QDSX, the PM6344 EQUAD, the and PM4388 TOCTL provide high density multi-channel solutions for the Basestation Controller Do wn l oa d ed by ab do u ra s ha d of bn ha cir Public Switched Telephone Network PROPRIETARY AND CONFIDENTIAL 33 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - V5.1 Interface Application V5.1 Interface 20 PM4314 PM6344 QDSX EQUAD 07 Switch Fabric 01 PM4314 PM6344 QDSX EQUAD LIU Framer 2A Processor us PM4314 PM6344 QDSX EQUAD PM7364 FREEDM t, PM4314 PM6344 QDSX EQUAD ug PM5342 PM5362 SPECTRA TUPP+ 155 :2 6: Figure 2 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 HDLC HDLC HDLC ,0 Central Office Switch PM4351 COMET on Th ur sd ay STM-1 Intel or Motorola P Line Card Line Card Line Card Line Card Low Power 3.3v Power Supply Pedestal-Mount Digital Loop Carrier Do wn l oa d ed by ab do u ra s ha d of bn ha cir o COMET used in conjunction with PM6344 EQUAD and PM7366 FREEDM-8 to provide a complete V5.1 solution for both the Access Network and the Central Office PROPRIETARY AND CONFIDENTIAL 34 Subscribers PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER BLOCK DIAGRAM RCLKI RDAT :2 RXRIN G 01 RXTIP RVREF 07 t, 20 RSYNC XCLK / V CLK TC L KI TCLKO TVR EF TXR IN G[2:1] TXTIP[2:1] TFP TD A T 6: 5 50 AM PMC-1970624 CSB 2A M PIF MicroProcessor Interface RDB W RB us A[8:0] ALE ,0 ay TOPS Timing Options sd IN TB CDRC Clock and Data Recovery CSD Clock Synthesis and Distribution TJAT Tra nsm it Digital Jitter Attenuator RS TB TD O TD I TC K TM S TR S TB ur JTAG Test Access Port RJAT Receive Digital Jitter Attenuator Th XPDE Pulse Density Enforcer PRGD 1/2 Pattern Generator/ Detector TPSC Per-DS0 Serial Controller o on XIBC Inband Loopback Code Generator ha cir T1-XBAS/ E1-TRAN BasicTransm itte r: Fram e Generation, Alarm Insertion, XBOC Signaling Insertion, Bit O riented Trunk Co nditioning Code Generator bn FRAM Framing RAM IBCD Inband Loopback Code Detector PM ON Performance Monitor Counters PDVD Pulse Density Viola tion Detector FRM R Frame Alignm ent, Alarm Extraction ALM I Alarm Integrator RBOC Bit Oriented Code Detector of TDPR#3 HDLC Transmitter ha d TDPR#2 HDLC Transmitter ra s RDLC#3 HDLC Receiver RXELST Elastic Store TXELST Elastic Store TDPR#1 HDLC Transmitter RDLC#2 HDLC Receiver RDLC#1 HDLC Receiver BTIF Backplane Tra nsm it Interface PRGD 1/2 Patte rn Generator / Detector RPSC Per-DS0 Serial Controller BRIF Backplane Receive Interface PROPRIETARY AND CONFIDENTIAL 35 BRSIG BRFP BRPCM BRCLK BTFP BTC LK BTS IG BTPC M Do wn l oa d ed by ab do u RLPS Receive LIU ug XLPG Transm it LIU D[7:0] E1/T1SIG X Signaling Extractor PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER DESCRIPTION :2 6: 6 50 AM PMC-1970624 20 07 01 The PM4351 Combined E1/T1 Transceiver (COMET) is a feature-rich monolithic integrated circuit suitable for use in long haul and short haul T1 and E1 systems with a minimum of external circuitry. The COMET is software configurable, allowing feature selection without changes to external wiring. ay ,0 2A ug us t, Analog circuitry is provided to allow direct reception of long haul E1 and T1 compatible signals with up to 36 dB cable loss (at 1.024 MHz in E1 mode) or up to 36 dB cable loss (at 772 kHz in T1 mode) using a minimum of external components. Typically, only line protection, a transformer and a line termination resistor are required. Digital line inputs are provided for applications not requiring a physical T1 or E1 interface. on Th ur sd The COMET recovers clock and data from the line and frames to incoming data. In T1 mode, it can frame to several DS-1 signal formats: SF, ESF, T1DM (DDS) and SLC(R)96. In E1 mode, the COMET frames to basic G.704 E1 signals and CRC-4 multiframe alignment signals, and automatically performs the G.706 interworking procedure. AMI, HDB3 and B8ZS line codes are supported. ra s ha d of bn ha cir o The COMET supports detection of various alarm conditions such as loss of signal, pulse density violation, Red alarm, Yellow alarm, and AIS alarm in T1 mode and loss of signal, loss of frame, loss of signaling multiframe and loss of CRC multiframe in E1 mode. The COMET also supports reception of remote alarm signal, remote multiframe alarm signal, alarm indication signal, and time slot 16 alarm indication signal in E1 mode. The presence of Yellow and AIS patterns in T1 mode and remote alarm and AIS patterns in E1 mode is detected and indicated. In T1 mode, the COMET integrates Yellow, Red, and AIS alarms as per industry specifications. In E1 mode, the COMET integrates Red and AIS alarms. by ab do u Performance monitoring with accumulation of CRC-6 errors, framing bit errors, line code violations, and loss of frame events is provided in T1 mode. In E1 mode, CRC-4 errors, far end block errors, framing bit errors, and line code violation are monitored and accumulated. Do wn l oa d ed The COMET provides three receive HDLC controllers for the detection and termination of messages on the ESF facility data link (T1) or national use bits (E1) and in any arbitrary time slot (T1 or E1). In T1 mode, the COMET also detects the presence of in-band loop back codes and ESF bit oriented codes. Detection and optional debouncing of the 4-bit Sa-bit codewords defined in ITU-T G.704 and ETSI 300-233 is supported. An interrupt may be generated on any change of state of the Sa codewords. PROPRIETARY AND CONFIDENTIAL 36 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 Dual (transmit and receive) elastic stores for slip buffering and rate adaptation to backplane timing are provided, as is a signaling extractor that supports signaling debounce, signaling freezing, idle code substitution, digital milliwatt tone substitution, data inversion, and signaling bit fixing on a per-channel basis. Receive side data and signaling trunk conditioning is also provided. ug us t, 20 In T1 mode, the COMET generates framing for SF, ESF and T1DM (DDS) formats. In E1 mode, the COMET generates framing for a basic G.704 E1 signal. The signaling multiframe alignment structure and the CRC multiframe structure may be optionally inserted. Framing can be optionally disabled. cir o on Th ur sd ay ,0 2A Internal analog circuitry allows direct transmission of long haul and short haul T1 and E1 compatible signals using a minimum of external components. Typically, only line protection, a transformer and an optional line termination resistor are required. Digitally programmable pulse shaping allows transmission of DSX-1 compatible signals up to 655 feet from the cross-connect, E1 short haul pulses into 120 ohm twisted pair or 75 ohm coaxial cable, E1 long haul pulses into 120 ohm twisted pair as well as long haul DS-1 pulses into 100 ohm twisted pair with integrated support for LBO filtering as required by the FCC rules. In addition, the programmable pulse shape extending over 5-bit periods allows customization of short haul and long haul line interface circuits to application requirements. Digital line inputs and outputs are provided for applications not requiring a physical T1 or E1 interface. ra s ha d of bn ha In the transmit path, the COMET supports signaling insertion, idle code substitution, digital milliwatt tone substitution, data inversion, and zero code suppression on a per-channel basis. Zero code suppression may be configured to Bell (bit 7), GTE, or DDS standards, and can also be disabled. Transmit side data and signaling trunk conditioning is also provided. Signaling bit transparency from the backplane may be enabled. ed by ab do u The COMET provides three transmit HDLC controllers. These controllers may be used for the transmission of messages on the ESF data link (T1) or national use bits (E1) and in any time slot. In T1 mode, the COMET can be configured to generate in-band loop back codes and ESF bit oriented codes. In E1 mode, transmission of the 4-bit Sa codewords defined in ITU-T G.704 and ETSI 300-233 is supported. Do wn l oa d The COMET provides optional jitter attenuation in both the transmit and receive directions. The COMET provides both a parallel microprocessor interface for controlling the operation of the device and serial PCM interfaces that allow backplane rates from 1.544 Mbit/s to 8.192 Mbit/s to be directly supported. Up to four COMET devices can be multiplexed on a byte-interleaved basis on a common bus with no PROPRIETARY AND CONFIDENTIAL 37 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 additional arbitration logic. The COMET supports the Mitel ST(R) bus, AT&T CHI(R) and MVIP standards. PROPRIETARY AND CONFIDENTIAL 38 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER PIN DIAGRAMS :2 6: 7 50 AM PMC-1970624 20 t, RAVS 1 RAVD1 62 61 us RAVD2 RXRING RXTIP 65 64 63 BTPC M BTS IG BTF P VDDI2 VSSI2 TC K ay sd ur Th 7 8 9 10 11 12 PM4351-RI 13 14 15 TDO TR STB 19 20 39 40 A[3] A[4] 36 37 38 39 A[1] A[2] D[7] A[0] 33 34 35 D[4] D[5] D[6] 30 31 32 D[3] VDDO3 VSSO 3 27 28 29 D[0] D[1] D[2] 25 26 24 RDB W RB INTB 22 23 d 21 CSB RS TB ha wn l oa d ed by ab do u ra s 54 53 52 BRCLK VDDO 1 VSSO 1 51 BRPCM BRSIG BRFP 47 46 VDDI1 VSSI1 BIA S 45 44 43 ALE A[8] A[7] 42 A[6] A[5] 41 Do PROPRIETARY AND CONFIDENTIAL RDA T RCLKI RSYNC 48 of 17 18 RVREF PIO TRIM F 56 55 50 49 (TOP VIEW ) 16 TM S TDI 57 on VDDO 2 VSSO 2 BTC LK 5 6 o TD A T TFP 4 cir TCLK O 60 59 58 ha XCLK TCLK I 1 2 3 bn TAV D1 TA VS 1 ,0 2A ug ATB Q AVD RAVS 2 70 69 68 67 66 TAV D4 TA VS 4 Q AV S TAV D2 TXTIP 1 TXRING 1 73 72 71 76 75 74 79 78 77 80 TAV D3 TVRE F TA VS 2 PM4351-RI COMET Pin Diagram TXRING 2 TXTIP 2 TA VS 3 Figure 3 07 01 The COMET is packaged in an 80-pin metric plastic quad flat pack (MQFP) package having a body size of 14 mm by 14 mm and a pin pitch of 0.65 mm. PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 PM4351-NI COMET Pin Diagram 01 Figure 4 6: 50 The COMET is also available in an 81 pin Chip Array Ball Grid Array (CABGA) package having a body size of 9 mm by 9 mm and a pin pitch of 0.8 mm. 8 7 6 5 4 3 1 A RAVD1 RXRING RAVD2 QAVD TAVD4 TVREF TAVS2 TXTIP2 TAVD1 A B PIO RAVS1 RAVS2 ATB TAVD3 TAVD2 TAVS3 TAVS1 TCLKI B C RSYNC TRIMF RXTIP TAVS4 TXRING XCLK/ TDAT TCLKO C ug us t, 20 9 ,0 TXRING VSSO1 BTCLK VDDO1 TFP D BTFP BTSIG TMS BTPCM E BRCLK RVREF QAVS E BRPCM RDAT VSSO2 VDDO2 F VSSI2 VDDI2 BRSIG BRFP D[5] D[3] TRSTB VDDI1 TCK F G ALE BIAS A[7] A[4] D[4] VDDO3 RDB TDI VSSI1 G H A[8] A[6] A[2] D[6] A[1] D[2] D[0] RSTB TDO H J A[5] A[3] A[0] VSSO3 D[1] INTB WRB CSB J 9 8 6 5 4 3 2 1 PROPRIETARY AND CONFIDENTIAL ur NC Th on cir ha of Do wn l oa d ed by ab do u ra s ha d 7 sd RCLKI o VCLK D D[7] TXTIP1 2 bn ay 1 2 2A 07 (Bottom View) 40 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER PIN DESCRIPTION -RI BTCLK I/O 01 Pin No. Function 07 Type -NI 10 20 Pin Name - Backplane Transmit Interface (4 pins) D3 Backplane Transmit Clock (BTCLK). In synchronous backplane applications, t, Table 1 :2 6: 8 50 AM PMC-1970624 us the BTCLK input may be a 1.544 MHz, 2.048 MHz, 3.088 MHz, 4.096 MHz, ug 8.192 MHz or 16.384 MHz clock with optional gapping for adaptation from non- 2A uniform system clocks. BTCLK can be configured as a line-rate output, in which case it is referenced to ,0 TCLKI or the receive recovered clock (loop timed). In T1 NxDS0 mode, BTCLK ay is gapped during the framing bit position and optionally for between 1 and 23 DS0 channels in the backplane data stream. In E1 NxDS0 mode, BTCLK is sd gapped optionally for between 1 and 31 time slots in the backplane data ur stream. Th When BTCLK is configured as an input, byte-interleaved backplanes are on supported. BTCLK may be configured to be active on either its rising or falling edge. cir o BTPCM and BTSIG are sampled on the active edge of BTCLK. Depending on its configuration, BTFP is either sampled or updated on the selected active After a reset, BTCLK is configured as an input. Do wn l oa d ed by ab do u ra s ha d of bn ha edge of BTCLK. PROPRIETARY AND CONFIDENTIAL 41 PM4351 COMET STANDARD PRODUCT DATA SHEET I/O Function -RI -NI 13 E4 6: Pin No. Backplane Transmit Frame Pulse (BTFP). When BTFP is configured as an 01 BTFP Type :2 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 50 PMC-1970624 input, it is used to frame align the transmitter to the system backplane. 07 T1 mode: 20 If only frame alignment is required, a pulse at least one BTCLK cycle wide must be provided on BTFP at multiples of 193 bit periods. If superframe alignment is us t, required, transmit superframe alignment must be enabled, and BTFP must be 2A E1 mode: ug brought high for at least one BTCLK cycle to mark bit 1 of frame 1 of every 12frame or 24-frame superframe. ,0 If basic frame alignment only is required, a pulse at least one BTCLK cycle ay wide must be provided on BTFP at multiples of 256 bit periods. If multiframe sd alignment is required, transmit multiframe alignment must be enabled, and BTFP must be brought high to mark bit 1 of frame 1 of every 16-frame signaling ur multiframe and brought low following bit 1 of frame 1 of every 16-frame CRC Th multiframe. This mode allows both multiframe alignments to be independently controlled using the single BTFP signal. Note that if the signaling and CRC on multiframe alignments are coincident, BTFP must pulse high for one BTCLK o cycle every 16 frames. cir When BTFP is configured as an output (only valid when the transmit backplane ha clock rate is no greater than 2.048 MHz), transmit frame alignment is derived 11 ha Input E1 After a reset, BTFP is configured as an input. Backplane Transmit PCM Data (BTPCM). The non-return to zero, digital data 1.544 Mbit/s, 2.048 Mbit/s or sub-rate NxDS0 data stream or may present a ab do u byte-interleaved 4.096 Mbit/s or 8.192 Mbit/s multiplexed data stream. The bit alignment of BTPCM relative to BTFP is configurable. Two mappings of a DS-1 into a 2.048 Mbit/s format are defined: every fourth timeslot unused and 24 contiguous timeslots. by ed optioned. The BTPCM signal is sampled on the configured active edge of BTCLK. Input Do wn l oa d BTSIG pulses high for one cycle to indicate the first bit of each frame or multiframe, as stream to be transmitted is input on this pin. BTPCM may present a ra s BTPCM d of bn internally and BTFP is updated on the configured active edge of BTCLK. BTFP PROPRIETARY AND CONFIDENTIAL 12 E3 Backplane Transmit Signaling (BTSIG). The BTSIG input signal contains the signaling bits for each channel in the transmit data frame, repeated for the entire superframe. Each channel's signaling bits are in bit locations 5, 6, 7 and 8 of the channel and are channel-aligned with the BTPCM data stream. The BTSIG signal is sampled on the configured active edge of BTCLK. 42 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 -RI BRCLK I/O 50 Pin No. Function 6: Type :2 Pin Name - Backplane Receive Interface (4 pins) -NI 54 01 Table 2 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 D8 Backplane Receive Clock (BRCLK). When BRCLK is configured as an input 07 and the elastic store is enabled, BRCLK may be either a 1.544 MHz, 20 2.048 MHz, 3.088 MHz, 4.096 MHz, 8.192 MHz or 16.384 MHz clock with t, optional gapping for adaptation to non-uniform backplane data streams. us When BRCLK is configured as a output, it can be either a 1.544 MHz or ug 2.048 MHz clock derived from the recovered line rate timing (available on RSYNC), with optional jitter attenuation. In T1 NxDS0 mode, BRCLK is gapped 2A during the framing bit position and optionally for between 1 and 23 DS0 ,0 channels in the backplane data stream. In E1 NxDS0 mode, BRCLK is gapped ay optionally for between 1 and 31 time slots in the backplane data stream. Either the rising or falling edge of BRCLK may be configured as the active sd edge. BRPCM and BRSIG are updated on the active edge of BRCLK. When ur BRFP is configured as an input, it is sampled on the active edge of BRCLK. on BRCLK. Th When BRFP is configured as an output, it is updated on the active edge of Do wn l oa d ed by ab do u ra s ha d of bn ha cir o After a reset, BRCLK is configured as an input. PROPRIETARY AND CONFIDENTIAL 43 PM4351 COMET STANDARD PRODUCT DATA SHEET BRFP I/O Function -RI -NI 49 F6 50 Pin No. 6: Type :2 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 Backplane Receive Frame Pulse (BRFP). When BRFP is configured as an 01 PMC-1970624 output, it indicates the frame alignment of BRPCM and BRSIG. BRFP is 07 generated on the active edge of BRCLK. 20 T1 mode: If basic frame alignment is desired, BRFP pulses high for one BRCLK cycle us t, during bit 1 of each 193-bit frame. Optionally, BRFP may pulse high every ug second frame to ease the identification of data link bits. If superframe alignment is desired, BRFP pulses high for one BRCLK cycle during bit 1 of 2A frame 1 of every 12-frame or 24-frame superframe. Optionally, BRFP may pulse high every second superframe to ease the conversion between SF and ,0 ESF. sd ay E1 mode: If basic frame alignment is desired, BRFP pulses high for one BRCLK cycle ur during bit 1 of each 256-bit frame. Optionally, BRFP may pulse high every Th second frame to ease the identification of NFAS frames. If multiframe alignment is desired, BRFP transitions high to mark bit 1 of frame 1 of every 16- on frame signaling multiframe and transitions low following bit 1 of frame 1 of every o 16-frame CRC multiframe. Note that if the signaling and CRC multiframe cir alignments are coincident, BRFP pulses high for one BRCLK cycle every 16 ha frames. of bn When BRFP is configured as an input, it is used to frame align the receive data d Output ab do u with After a reset, BRFP is configured as an input. E9 Backplane Receive PCM Data (BRPCM). BRPCM contains the recovered data stream passed through the elastic store, signaling extractor and per-DS0 serial controller. When the receive elastic store is not bypassed, the BRPCM stream is aligned to the backplane input timing. When BRCLK is either 4.096 MHz, 8.192 MHz or 16.384 MHz, BRPCM can be tristated and is only active during programmable timeslots. This allows byte interleaving of PCM data streams from up to 4 COMET devices with no external logic. After a reset, BRPCM is high impedance. BRPCM is updated on the active edge of BRCLK. Do wn l oa d ed by Tristate 51 at least one BRCLK cycle wide must be provided on BRFP a maximum of once every frame (193 bit periods in T1 mode or 256 bit periods in E1 mode). BRFP is sampled on the active edge of BRCLK. ha ra s BRPCM to the backplane frame alignment. When frame alignment is required, a pulse PROPRIETARY AND CONFIDENTIAL 44 PM4351 COMET STANDARD PRODUCT DATA SHEET Output Function -RI -NI 50 F7 6: Pin No. :2 BRSIG Type Backplane Receive Signaling (BRSIG). BRSIG contains the extracted signaling 01 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 50 PMC-1970624 with bits for each channel in the frame, repeated for the entire superframe. Each channel's signaling bits are valid in bit locations 5, 6, 7 and 8 of the channel 07 Tristate and are channel-aligned with the BRPCM data stream. When the RX-ELST is 20 not by-passed, the BRSIG stream is aligned to the backplane input timing. t, When BRCLK is either 4.096 MHz, 8.192 MHz or 16.384 MHz, BRSIG can be us tristated and is only active during programmable timeslots to allow byte ug interleaving of signaling data streams from up to 4 COMET devices with no 2A external logic. After a reset, BRSIG is high impedance. Pin No. -RI sd Type Function ur Pin Name - Transmit Line Interface (6 pins) Th Table 3 ay ,0 BRSIG is updated on the active edge of BRCLK. -NI Analog 73 D5 Transmit Analog Positive Pulse (TXTIP1 and TXTIP2). When the transmit Output 79 A2 analog line interface is enabled, the TXTIP1 and TXTIP2 analog outputs drive o on TXTIP1 TXTIP2 cir the transmit line pulse signal through an external matching transformer. Both TXTIP1 and TXTIP2 are normally connected to the positive lead of the of bn ha transformer primary. Two outputs are provided for better signal integrity and Output 72 C5 C4 analog line interface is enabled, the TXRING1 and TXRING2 analog outputs Both TXRING1 and TXRING2 are normally connected to the negative lead of the transformer primary. Two outputs are provided for better signal integrity and should be shorted together on the board. by the XLPG Line Driver Configuration register (address 0F0H) must be ed oa d Transmit Analog Negative Pulse (TXRING1 and TXRING2). When the transmit After a reset, TXRING1 and TXRING2 are high impedance. The HIGHZ bit of programmed to logic 0 to remove the high impedance state. Digital Output Do wn l TDAT XLPG Line Driver Configuration register (address 0F0H) must be programmed drive the transmit line pulse signal through an external matching transformer. ab do u 80 After a reset, TXTIP1 and TXTIP2 are high impedance. The HIGHZ bit of the to logic 0 to remove the high impedance state. d TXRING2 ha Analog ra s TXRING1 should be shorted together on the board. PROPRIETARY AND CONFIDENTIAL 6 C2 Transmit Digital PCM Data (TDAT). When the transmit digital line interface is enabled, the TDAT output provides the line side NRZ PCM transmit data. This mode may be used in applications not requiring a physical T1/E1 interface (e.g. interfacing to HDSL transceivers). TDAT is updated on the either the rising or falling (default) edge of TCLKO. 45 PM4351 COMET STANDARD PRODUCT DATA SHEET Pin No. -RI Digital -NI 7 D1 Transmit Digital Frame Pulse (TFP). When the transmit digital line interface is 01 TFP Function 6: Type :2 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 50 PMC-1970624 Output enabled, the TFP output indicates frame alignment of the line side transmitted 07 PCM stream (TDAT). This mode may be used in applications not requiring a physical T1/E1 interface (e.g. interfacing to HDSL transceivers). TFP is Pin No. -RI RXTIP Analog Function -NI 63 us ug Type 2A Pin Name - Receive Line Interface (4 pins) C7 Receive Analog Positive Pulse (RXTIP). When the analog receive line ,0 Table 4 t, 20 updated on the either the rising or falling (default) edge of TCLKO. interface is enabled, RXTIP samples the received line pulse signal from an ay Input sd external isolation transformer. RXTIP is normally connected directly to the Analog 64 A8 Receive Analog Negative Pulse (RXRING). When the analog receive line Th RXRING ur positive lead of the receive transformer secondary. Input interface is enabled, RXRING samples the received line pulse signal from an on external isolation transformer. RXRING is normally connected directly to the Input 57 E8 Receive Digital Line Data (RDAT). When the digital receive interface is cir RDAT o negative lead of the receive transformer secondary. enabled, the RDAT input samples the line side recovered NRZ PCM data of bn ha stream. This mode may be used in applications not requiring a physical T1/E1 56 d Input D9 ha RCLKI Receive Digital Line Clock (RCLKI). When the digital receive line interface is (e.g. interfacing to HDSL transceivers). RCLKI samples the receive PCM stream (RDAT) on its rising (default) or falling edge. - Timing Options Control (5 pins) Type I/O Pin No. -RI -NI 59 B9 Function Programmable I/O. PIO is an input/output pin controlled by a COMET register bit. As an output, the PIO bit can, under software control, be used to configure external circuitry dependent upon the mode of the COMET device. As an input, the state of the PIO pin can be read via a register bit. Do wn l oa d PIO edge of RCLKI. This mode may be used in applications not requiring a physical T1/E1 interface ra s ed Pin Name data recovery is disabled. RDAT is sampled on the rising (default) or falling enabled, the externally recovered line rate clock must be provided on RCLKI. ab do u by Table 5 interface (e.g. interfacing to HDSL transceivers). In digital mode, clock and PROPRIETARY AND CONFIDENTIAL 46 PM4351 COMET STANDARD PRODUCT DATA SHEET Pin No. -RI Output -NI 5 C1 Transmit Clock Output (TCLKO). TCLKO is a clock at the transmit line rate and 01 TCLKO Function 6: Type :2 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 50 PMC-1970624 may be used by external circuits as a transmit clock reference. When the 07 digital transmit line interface is enabled, TDAT and TFP are updated on the RSYNC Output 55 20 either the rising or falling (default) edge of TCLKO. C9 Recovered Clock Synchronization Signal (RSYNC). This output signal is the us t, dejittered recovered receiver line rate clock (1.544 or 2.048 MHz) or, optionally, the recovered clock synchronously divided by 193 (T1 mode) or 256 (E1 mode) ug to create a 8 kHz timing reference signal. When 8 kHz, the RSYNC phase is 2A independent of frame alignment and is not affected by framing events. When the COMET is in a loss of signal state, RSYNC is derived from the XCLK TCLKI Input 4 ay ,0 input or, optionally, is held high. B1 Transmit Clock Reference (TCLKI). TCLKI may be used as a reference for the sd transmit line rate generation. TCLKI may be any multiple of 8 kHz (N x 8 kHz, ur where 1N256) so long as TCLKI has minimal jitter when divided down to Th 8 kHz. When the TCLKI frequency differs from the transmit line rate, the transmit jitter attenuation block (TJAT) must be enabled to attenuate jitter on on the transmit clock in accordance with AT&T TR-62411 and ETS 300 011. When o the TCLKI frequency is the same as the transmit line rate, TCLKI is optionally cir jitter attenuated by the TJAT in accordance with AT&T TR-62411 and ETS 300 011. When TCLKI jitter attenuation is enabled, the TCLKI frequency should be Input 3 C3 ha ra s XCLK is a nominally jitter-free 50% duty cycle clock at 1.544 MHz in T1 mode In T1 mode, a 2.048 MHz clock may be used as a reference. When used in ab do u ed oa d wn l Do ATB Crystal Clock Input (XCLK). This signal provides a stable, global timing this way, however, the intrinsic jitter specifications to AT&T TR62411 may not be met. Vector Clock (VCLK). The VCLK signal is used during COMET production test to verify internal functionality. Table 6 Pin Name the receive recovered clock instead. and 2.048 MHz in E1 mode. by VCLK The COMET may be configured to ignore the TCLKI input and utilize BTCLK or reference for the COMET internal circuitry via an internal clock synthesizer. d XCLK / of bn ha programmed into the TJAT Jitter Attenuation Divider N1 Control register. - Analog Support Circuitry (4 pins) Type Analog I/O PROPRIETARY AND CONFIDENTIAL Pin No. -RI -NI 68 B6 Function Analog Test Bus (ATB). Reserved for COMET production test. This pin must be connected to an analog ground for normal operation. 47 PM4351 COMET STANDARD PRODUCT DATA SHEET TVREF Analog Function -RI -NI 76 A4 Transmit Voltage Reference (TVREF). This pin is reserved for a precision I/O analog voltage or current reference. Analog 60 D7 Receive Voltage Reference (RVREF). This pin is reserved for a precision 07 RVREF 50 Pin No. 6: Type :2 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 01 PMC-1970624 analog voltage or current reference. This pin must be connected to an external 20 I/O RC network consisting of a 100 kohm resistor connected in parallel with a 58 us Input C8 Trim Fuse. This pin is reserved for production purposes. The TRIMF signal is ug TRIMF t, 10 nF capacitor to analog ground. used during COMET production test to control the trimming of fuses. This pin TCK ay ,0 Input Pin No. Function -RI -NI 16 F1 sd Type ur Pin Name - JTAG (IEEE 1149.1) Boundary Scan Test Interface (5 pins) Test Clock (TCK). The test clock (TCK) signal provides timing for test Th Table 7 2A must be tied low for normal operation. TMS Input 17 on operations that are carried out using the IEEE P1149.1 test access port. E2 Test Mode Select (TMS). The test mode select (TMS) signal controls the test o operations that are carried out using the IEEE P1149.1 test access port. TMS 18 G2 Input 20 COMET via the IEEE P1149.1 test access port. TDI is sampled on the rising edge of TCK. TDI has an integral pull-up resistor. Test Data Output (TDO). The test data output (TDO) signal carries test data out of the COMET via the IEEE P1149.1 test access port. TDO is updated on the falling edge of TCK. TDO is a tristate output which is tristated except when scanning of data is in progress. F3 Active Low Test Reset (TRSTB). The test reset (TRSTB) signal provides an asynchronous COMET test access port reset via the IEEE P1149.1 test access port. TRSTB is a Schmitt triggered input with an integral pull-up resistor. The JTAG TAP controller must be initialized when the COMET is powered up. If the JTAG port is not used, TRSTB should be connected to the RSTB input. Do wn l oa d ed by ab do u TRSTB H1 of ra s Tristate 19 d Output with ha TDO Test Data Input (TDI). The test data input (TDI) signal carries test data into the ha Input bn TDI cir is sampled on the rising edge of TCK. TMS has an integral pull-up resistor. PROPRIETARY AND CONFIDENTIAL 48 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 CSB Input 50 Pin No. Function -RI -NI 21 J1 6: Type :2 Pin Name - Microprocessor Interface (23 pins) 01 Table 8 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Active Low Chip Select (CSB). CSB must be low to enable COMET register 07 accesses. CSB must go high at least once after power up to clear internal test 20 modes. If CSB is not used, it should be tied to an inverted version of RSTB, in Input 23 G3 Active Low Read Enable (RDB). RDB is pulsed low to enable a COMET us RDB t, which case, RDB and WRB determine register accesses. ug register read access. The COMET drives the D[7:0] bus with the contents of WRB Input 24 2A the addressed register while RDB and CSB are both low. J2 Active Low Write Strobe (WRB). WRB is pulsed low to enable a COMET ,0 register write access. The D[7:0] bus contents are clocked into the addressed Input 45 G9 Address Latch Enable (ALE). This signal latches the address bus contents, sd ALE ay normal mode register on the rising edge of WRB while CSB is low. ur A[8:0], when low, allowing the COMET to be interfaced to a multiplexed Bi-directional Data Bus (D[7:0]). This bus is used during read and write accesses to internal COMET registers. 27 J4 D[2] 28 H4 D[3] 29 F4 D[4] 32 G5 D[5] 33 F5 D[6] 34 D[7] 35 bn ha D[1] on H3 o 26 cir I/O D[0] Th address/data bus. When ALE is high, the address latches are transparent. ha d of H6 J7 J6 Address bus (A[8:0]). This bus selects specific registers during COMET register 37 H5 accesses. 38 H7 39 J8 40 G6 41 J9 42 H8 A[7] 43 G7 A[8] 44 H9 22 H2 Input A[1] ab do u A[2] A[3] oa d ed A[6] by A[4] A[5] RSTB Input Do wn l 36 ra s A[0] PROPRIETARY AND CONFIDENTIAL Active Low Reset (RSTB). When forced low, RSTB will asynchronously reset the COMET. RSTB is a Schmitt-trigger input with integral pull-up. When resetting the device, RSTB must be asserted for a minimum of 100 ns to ensure that the COMET is completely reset. 49 PM4351 COMET STANDARD PRODUCT DATA SHEET OD Function -RI -NI 25 J3 6: Pin No. :2 INTB Type Active Low Open-drain Interrupt (INTB). INTB drives low when an unmasked 01 Pin Name COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 50 PMC-1970624 Output interrupt event is detected on any of the internal interrupt sources. Note that 07 INTB will remain low until all active, unmasked interrupt sources are Pin No. -RI D2 Output Power Pins (VDDO[3:1]). The output power pins should be connected VDDO2 8 E6 to a well-decoupled +3.3 V DC supply in common with VDDI. VDDO3 30 G4 52 D4 Output Ground Pins (VSSO[3:1]). The output ground pins should be connected to GND in common with VSSI. ay 9 E7 VSSO3 31 J5 48 F2 Internal Power Pins (VDDI[2:1]). The internal power pins should be connected 14 F8 to a well-decoupled +3.3 V DC supply in common with VDDO. 47 G1 15 F9 VSSI1 Ground VSSI2 Input 46 G8 d of BIAS Analog 1 ab do u Power TAVD4 Analog ed by TAVD3 Analog Power wn l oa d TAVS1 Analog 74 A1 Analog TAVS3 Ground PROPRIETARY AND CONFIDENTIAL on +5 V Bias (BIAS). The BIAS input facilitates 5 V tolerance on the inputs. BIAS must be connected to a well-decoupled +5 V rail if 5 V tolerant inputs are required. If 5 V tolerant inputs are not required, BIAS must be connected to a Transmit Analog Power (TAVD1). TAVD1 provides power for the transmit LIU reference circuitry. TAVD1 should be connected to analog +3.3 V. B4 Transmit Analog Power (TAVD2, TAVD3). TAVD2 and TAVD3 supply power for 77 B5 the transmit LIU output drivers. TAVD2 and TAVD3 should be connected to 71 A5 analog +3.3 V. Transmit Analog Power (TAVD4). TAVD4 supplies power for the transmit clock synthesis unit. TAVD4 should be connected to analog +3.3 V. 2 B2 Ground TAVS2 connected to GND in common with VSSO. VDDI[3:1]. Power TAVD2 Internal Ground Pins (VSSI[2:1]). The internal ground pins should be well-decoupled 3.3 V DC supply together with the power pins VDDO[3:1] and ha ra s TAVD1 o VDDI2 ha Power bn VDDI1 Th VSSO2 cir Ground ,0 53 VSSO1 Do t, -NI sd Power Function ur VDDO1 us Type ug Pin Name - Power and Ground (25 pins) 2A Table 9 20 acknowledged at their source at which time, INTB will tristate. Transmit Analog Ground (TAVS1). TAVS1 provides ground for the transmit LIU reference circuitry. TAVS1 should be connected to analog GND. 75 78 A3 Transmit Analog Ground (TAVS2A, TAVD2B). TAVS2A and TAVS2B supply B3 ground for the transmit LIU output drivers. TAVS2A and TAVS2B should be connected to analog GND. 50 PM4351 COMET STANDARD PRODUCT DATA SHEET Pin No. -RI Analog -NI 70 C6 Transmit Analog Ground (TAVS4). TAVS supplies ground for the transmit clock 01 TAVS4 Function 6: Type :2 Pin Name COMBINED E1/T1 TRANSCEIVER Ground Analog synthesis unit. TAVS4 should be connected to analog GND. 61 A9 Receive Analog Power (RAVD1). RAVD1 supplies power for the receive LIU 07 RAVD1 65 A7 Receive Analog Power (RAVD2). RAVD2 supplies power for the receive LIU t, Analog input equalizer. RAVD1 should be connected to analog +3.3 V. 20 Power RAVD2 62 B8 Receive Analog Ground (RAVS1). RAVS1 supplies power for the receive LIU ug Analog peak detect and slicer. RAVD2 should be connected to analog +3.3 V. us Power RAVS1 Analog input equalizer. RAVS1 should be connected to analog GND. 66 2A Ground RAVS2 B7 Receive Analog Ground (RAVS2). RAVS2 supplies power for the receive LIU 67 A6 Quiet Analog Power (QAVD). QAVD supplies power for the core analog ay Analog peak detect and slicer. RAVS2 should be connected to analog GND. ,0 Ground QAVD 69 D6 Quiet Analog Ground (QAVS). QAVS supplies ground for the core analog ur Analog circuitry. QAVD should be connected to analog +3.3 V. sd Power QAVS AM ISSUE 11 50 PMC-1970624 circuitry. QAVS should be connected to analog GND. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th Ground PROPRIETARY AND CONFIDENTIAL 51 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 - PM4351-RI Pin Summary 50 Table 10 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: Function 01 Backplane Transmit Interface 07 Backplane Receive Interface 20 Transmit Line Interface t, Receive Line Interface us Timing Options Control 2A ug Analog Support Circuitry JTAG (IEEE 1149.1) Boundary Scan Test Interface ay ,0 Microprocessor Interface sd Power and Ground ur Total Functions Pins 6 pins 4 pins 5 pins 4 pins 5 pins 23 pins 25 pins 80 pins 80 pins Pins cir Function 4 pins Backplane Receive Interface 4 pins Transmit Line Interface 6 pins Receive Line Interface 4 pins Timing Options Control 5 pins Analog Support Circuitry 4 pins JTAG (IEEE 1149.1) Boundary Scan Test Interface 5 pins ab do u ra s ha d of bn ha Backplane Transmit Interface 23 pins Power and Ground 25 pins Total Functions Pins 80 pins ed by Microprocessor Interface 1 pin oa d Unused Pins 81 pins wn l Total Do 4 pins PM4351-NI Pin Summary o Table 11 4 pins on Th Total Pins Notes on Pin Description: PROPRIETARY AND CONFIDENTIAL 52 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 1. All COMET digital inputs and bi-directional pins present minimum capacitive loading and operate at TTL logic levels. 20 07 01 :2 2. All COMET digital outputs and bi-directional pins have at least 2 mA drive capability. The BTCLK and BRCLK outputs, have 6 mA drive capability. The transmit analog outputs (TXTIP and TXRING) have built-in short circuit current limiting. us t, 3. Inputs RSTB, TMS, TDI and TRSTB have internal pull-up resistors. ,0 2A ug 4. The VSSI and VSSO ground pins are not internally connected together. Failure to connect these pins externally may cause malfunction or damage the COMET. ur sd ay 5. The VDDI and VDDO power pins are not internally connected together. Failure to connect these pins externally may cause malfunction or damage the COMET. Th 6. The recommended power supply sequencing is as follows: cir o on a) During power-up, the voltage on the BIAS pin must be kept equal to or greater than the voltage on the VDDO3, VDDO2, VDDO1, VDDI2 and VDDI1 pins, to avoid damage to the device. of bn ha b) VDDI power must be supplied either before VDDO or simultaneously with VDDO. Connection of VDDI and VDDO to a common VDD power plane is recommended. ra s ha d c) The VDDI power must be applied before input pins are driven or the input current per pin be limited to less than the maximum DC input current specification (20 mA). ed by ab do u d) Analog power supplies (TAVD1, TAVD2, TAVD3, TAVD4, RAVD1, RAVD2, QAVD) must be applied after both VDDI and VDDO have been applied or they must be current limited to the maximum latch-up current specification (100 mA). In operation, the differential voltage measured between AVD supplies and VDDI must be less than 0.5 V. The relative power sequencing of the multiple AVD power supplies is not important. Do wn l oa d e) Power down the device in the reverse sequence. PROPRIETARY AND CONFIDENTIAL 53 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER FUNCTIONAL DESCRIPTION 9.1 Receive Interface 01 :2 6: 9 50 AM PMC-1970624 ug us t, 20 07 Two basic receive options are available: the receive stream is presented as a TTL-compatible unipolar signal with an associated clock, or the receive data is reconstructed from unequalized pulses from a center tapped signal transformer. See Figure 5 for the recommended external analog circuitry. ,0 2A When the digital receive interface is enabled, the RDAT signal is expected to carry a decoded serial bit stream. RDAT can be sampled on either the rising or falling RCLKI edge. The polarity of RDAT can also be inverted. Th ur sd ay The analog receive interface is configurable to operate in both E1 and T1 shorthaul and long-haul applications. Short-haul T1 is defined as transmission over less than 655 ft of cable. Short-haul E1 is defined as transmission on any cable that attenuates the signal by less than 6 dB. cir o on For long-haul signals, unequalized long- or short-haul bipolar alternate mark inversion (AMI) signals are received as the differential voltage between the RXTIP and RXRING inputs. Do wn l oa d ed by ab do u ra s ha d of bn ha For short-haul, the slicing threshold is set to a fraction of the input signal's peak amplitude, and adapts to changes in this amplitude. The slicing threshold is 67% and 50% for DSX-1 and E1 applications, respectively. Abnormally low input signals are detected when the input level is below 140 mV for E1 and 105 mV for T1. PROPRIETARY AND CONFIDENTIAL 54 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - External Analog Interface Circuits 01 :2 6: Figure 5 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 t, 20 07 TXT IP 1 TXT IP 2 2A ug us TV RE F TXR IN G 1 ,0 TXR IN G 2 ur sd ay AT B on Th RXT IP ha cir o RXR IN G d of bn TXT IP 1 TXT IP 2 ra s ab do u TXR IN G 1 ha TV RE F TXR IN G 2 ed by AT B Do wn l oa d RXT IP RXR IN G Figure 5 gives the recommended external protection circuitry for two cases: PROPRIETARY AND CONFIDENTIAL 55 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 1) for systems requiring phantom feed or inter-building line protection 2) for systems with no DC current requirements or intra-building line protection. 07 01 :2 See Table 12 for the descriptions of components for Figure 5. See Table 14 for the descriptions of values for the transformer turns ratio, n, Rt1 and Rt2 for Figure 5. Description Part # Source TC250-180 Raychem LC01-6 Semtech LC03-6 Semtech Surge Protector Diode Array SRDA3.3-4 Semtech Bi-directional Transient Surge Suppressors SGT27B13 Harris 50436 (single) T1137 (dual) TG23-1505NS (single) TG23-1505N1 (dual) Midcom Pulse Halo sd Component ,0 - External Component Descriptions ay Table 12 2A ug us t, 20 Figure 5 assumes primary protectors (like carbon blocks) are also present. The protection resistors (PTCs) of 1 (but can be up to about 2) are optional, but if not included then 1 to 2 resistor with a series fuse should be used instead. Note that the crowbar devices (Z1 - Z4) are not required if the transformer's isolation rating is not exceeded. Typically 12.7 1% Resistors (see Table 14) Rterm 18.2 1% Resistor for T1 & 120 E1 13 1% Resistor for 75 E1 (assuming a 1:2.42 transformer) cir o on Th ur Rt1 & Rt2 C0 & C1 ha 4.7F10% Capacitors of bn PTC1 - PTC4 1 Positive Temperature Coefficient R ra s ha d TVS1 & TVS2 6V Bi-directional Transient Voltage Suppressor Diode ab do u TVS2 & TVS3 6V Bi-directional Transient Voltage Suppressor Diode D1 by Z1 - Z4 Generally 1:2.42CT Transformers (see Table 14) Do wn l oa d ed T1 & T2 PROPRIETARY AND CONFIDENTIAL 56 Halo PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50436 (single) T1137 (dual) TG23-1505NS (single) TG23-1505N1 (dual) :2 6: 50 Generally 1:2.42CT Transformers with centre taps floating (see Table 14) Midcom Pulse Halo Halo - Typical Input Return Loss at Receiver ug Table 13 us t, 20 07 01 T3 & T4 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 n Rterm T1: Zo=100 1:2.42 18.2 1% 30.2dB E1: Zo=120 1:2.42 18.2 1% 24.4dB E1: Zo=75 1:2.42 13.0 1% 43.3dB Typical IRL Th ur sd ay ,0 2A Case on - Termination Resistors, Transformer Ratios and TRL o Table 14 n Rt1 Rt2 Typical TRL 1:2.42 12.7 1% 12.7 1% 14.1dB cir Case ha SH T1: Zo=100 bn SH T1: Zo=100 1:2.42 0dB 1:2.42 12.7 1% 12.7 1% 19.4dB 1:2.42 1:2.421 12.7 1% 8.06 1% 12.7 1% 8.06 1% 9.6dB 18.8dB 1:2.42 12.7 1% 12.7 1% 14.1dB LH T1 LBO=-7.5dB: Zo=100 1:2.42 12.7 1% 12.7 1% 14.1dB LH T1 LBO=-15dB: Zo=100 1:2.42 12.7 1% 12.7 1% 14.1dB LH T1 LBO=-22.5dB: Zo=100 1:2.42 12.7 1% 12.7 1% 14.1dB d ra s ha SH E1: Zo=75 SH E1: Zo=751 of SH E1: Zo=120 by ab do u LH T1 LBO=0dB: Zo=100 Clock and Data Recovery (CDRC) Do wn l 9.2 oa d ed Notes: 1) Headroom power is about 30% higher in this case. The Clock and Data Recovery function is provided by the Clock and Data Recovery (CDRC) block. The CDRC provides clock and PCM data recovery, PROPRIETARY AND CONFIDENTIAL 57 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 ,0 2A ug us t, 20 07 01 :2 6: 50 B8ZS and HDB3 decoding, line code violation detection, and loss of signal detection. It recovers the clock from the incoming RZ data pulses using a digital phase-locked-loop and reconstructs the NRZ data. Loss of signal is indicated after a programmable threshold of consecutive bit periods of the absence of pulses on both the positive and negative line pulse inputs and is cleared after the occurrence of a single line pulse. An alternate loss of signal indication is provided which is cleared upon meeting an 1-in-8 pulse density criteria for T1 and a 1-in-4 pulse density criteria for E1. If enabled, a microprocessor interrupt is generated when a loss of signal is detected and when the signal returns. A line code violation is defined as a bipolar violation (BPV) for AMI-coded signals, is defined as a BPV that is not part of a zero substitution code for B8ZS-coded signals, and is defined as a bipolar violation of the same polarity as the last bipolar violation for HDB3-coded signals. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay In T1 mode, the input jitter tolerance of the COMET complies with the Bellcore Document TA-TSY-000170 and with the AT&T specification TR62411, as shown in Figure 6. The tolerance is measured with a QRSS sequence (220-1 with 14 zero restriction). The CDRC block provides two algorithms for clock recovery that result in differing jitter tolerance characteristics. The first algorithm (when the ALGSEL register bit is logic 0) provides good low frequency jitter tolerance, but the high frequency tolerance is close to the TR62411 limit. The second algorithm (when ALGSEL is logic 1) provides much better high frequency jitter tolerance at the expense of the low frequency tolerance; the low frequency tolerance of the second algorithm is approximately 80% that of the first algorithm. PROPRIETARY AND CONFIDENTIAL 58 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - T1 Jitter Tolerance 6: Figure 6 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 ALGSEL=1 at 772 kHz with 36 dB of attenuation 10 us t, 20 ALGSEL=0 at 772 kHz with 36 dB of attenuation Acceptable Range ,0 2A ug Sine Wave Jitter Amplitude P. to P. (UI) Log Scale ur sd ay 1.0 Bellcore Spec. Th 0.3 AT&T Spec. cir o on 0.2 0.30 0.31 1.0 10 100 bn 0.1 ha 0.1 of Sine Wave Jitter Frequency (kHz) Log Scale Do wn l oa d ed by ab do u ra s ha d For E1 applications, the input jitter tolerance complies with the ITU-T Recommendation G.823 "The Control of Jitter and Wander Within Digital Networks Which are Based on the 2048 kbit/s Hierarchy." Figure 7 illustrates this specification and the performance of the phase-locked loop when the ALGSEL register bit is logic 0. PROPRIETARY AND CONFIDENTIAL 59 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Compliance with ITU-T Specification G.823 for E1 Input Jitter 01 20 SINEWAVE JITTER AMPLITUDE P. TO P. (UI) LOG SCALE 07 DPLL TOLERANCE WITH AMI ENCODED 15 2 -1 PRBS 10 :2 6: Figure 7 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 us t, DPLL TOLERANCE WITH HDB3 ENCODED 2 15-1 PRBS ,0 2A ug IN SPEC REGION ay 1.5 Th ur sd 1 cir o on REC. G823 JITTER TOLERANCE SPECIFICATION d 10 3 2.4 10 ha 0.1 of bn ha 0.2 4 1.8 10 5 9.3 ab do u ra s SINEWAVE JITTER FREQUENCY, Hz - LOG SCALE T1 Framer Do wn l oa d ed by The T1 framing function is provided by the T1-FRMR block. This block searches for the framing bit position of SF, ESF, J1, T1DM or SLC(R)96 framing formats in the incoming recovered PCM stream. When searching for frame, the T1-FRMR examines each of the 193 (SF, T1DM or SLC(R)96) or each of 4*193 (ESF or J1) framing bit candidates concurrently. The time required to find frame alignment to an error-free PCM stream containing randomly distributed channel data (i.e. each bit in the channel data has a 50% probability of being 1 or 0) is dependent upon the framing format. For standard superframe format (SF, also known as D4 format), the T1-FRMR block will PROPRIETARY AND CONFIDENTIAL 60 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 determine frame alignment within 4.4 ms 99 times out of 100. For SLC(R)96 format, the T1-FRMR will determine frame alignment within 9.9 ms 99 times out of 100. For extended superframe format (ESF) and J1, the T1-FRMR will determine frame alignment within 15 ms 99 times out of 100. For T1DM format, the T1-FRMR will determine frame alignment within 1.125 ms 99 times out of 100. 2A ug us t, 20 Once the T1-FRMR has found frame, the incoming PCM data is continuously monitored for framing bit errors, bit error events (a framing bit error in SF or SLC(R)96, a framing bit error or sync bit error in T1DM, or a CRC-6 error in ESF and J1), and severe errored framing events. The T1-FRMR also detects loss of frame, based on a selectable ratio of framing bit errors. Th ur sd ay ,0 The T1-FRMR extracts the Yellow alarm signal bits from the incoming PCM data stream in SF and SLC(R)96 framing formats, and extracts the Y-bit from the T1DM sync word in T1DM framing format. The T1-FRMR also extracts the SLC(R)96 data link in SLC(R)96 framing format (with external logic), extracts the facility data link bits in the ESF and J1 framing formats, and extracts the R-bit from the T1DM sync word in T1DM framing format. cir E1 Framer ha 9.4 o on The T1-FRMR can also be disabled to allow reception of unframed data. ha d of bn The E1 framing function is provided by the E1-FRMR block. The E1-FRMR block searches for basic frame alignment, CRC multiframe alignment, and channel associated signaling (CAS) multiframe alignment in the incoming recovered PCM stream. Do wn l oa d ed by ab do u ra s Once the E1-FRMR has found basic (or FAS) frame alignment, the incoming PCM data stream is continuously monitored for FAS/NFAS framing bit errors. Framing bit errors are accumulated in the framing bit error counter contained in the PMON block. Once the E1-FRMR has found CRC multiframe alignment, the PCM data stream is continuously monitored for CRC multiframe alignment pattern errors, and CRC-4 errors. CRC-4 errors are accumulated in the CRC error counter of the PMON block. Once the E1-FRMR has found CAS multiframe alignment, the PCM data is continuously monitored for CAS multiframe alignment pattern errors. The E1-FRMR also detects and indicates loss of basic frame, loss of CRC multiframe, and loss of CAS multiframe, based on user-selectable criteria. The reframe operation can be initiated by software (via the E1-FRMR Frame Alignment Options Register), by excessive CRC errors, or when CRC multiframe alignment is not found within 400 ms. The E1-FRMR also identifies the position of the frame, the CAS multiframe, and the CRC multiframe. PROPRIETARY AND CONFIDENTIAL 61 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 20 07 01 :2 6: 50 The E1-FRMR extracts the contents of the International bits (from both the FAS frames and the NFAS frames), the National bits, and the Extra bits (from timeslot 16 of frame 0 of the CAS multiframe), and stores them in the E1-FRMR International/National Bits register and the E1-FRMR Extra Bits register. Moreover, the FRMR also extracts submultiframe-aligned 4-bit codewords from each of the National bit positions Sa4 to Sa8, and stores them in microprocessoraccessible registers that are updated every CRC submultiframe. on Th ur sd ay ,0 2A ug us t, The E1-FRMR identifies the raw bit values for the Remote (or distant frame) Alarm (bit 3 in timeslot 0 of NFAS frames) and the Remote Signaling Multiframe (or distant multiframe) Alarm (bit 6 of timeslot 16 of frame 0 of the CAS multiframe) via the E1-FRMR International/National Bits Register, and the E1-FRMR Extra Bits Register respectively. Access is also provided to the "debounced" remote alarm and remote signaling multiframe alarm bits which are set when the corresponding signals have been a logic 1 for 2 or 3 consecutive occurrences, as per Recommendation O.162. Detection of AIS and timeslot 16 AIS are provided. AIS is also integrated, and an AIS Alarm is indicated if the AIS condition has persisted for at least 100 ms. The out of frame (OOF=1) condition is also integrated, indicating a Red Alarm if the OOF condition has persisted for at least 100 ms. bn ha cir o An interrupt may be generated to signal a change in the state of any status bits (OOF, OOSMF, OOCMF, AIS or RED), and to signal when any event (RAI, RMAI, AISD, COFA, FER, SMFER, CMFER, CRCE or FEBE) has occurred. Additionally, interrupts may be generated every frame, CRC submultiframe, CRC multiframe or signaling multiframe. ha d of Basic Frame Alignment Procedure ab do u ra s The E1-FRMR searches for basic frame alignment using the algorithm defined in ITU-T Recommendation G.706 sections 4.1.2 and 4.2. The algorithm finds frame alignment by using the following sequence: by 1. Search for the presence of the correct 7-bit FAS (`0011011'); oa d ed 2. Check that the FAS is absent in the following frame by verifying that bit 2 of the assumed non-frame alignment sequence (NFAS) TS 0 byte is a logic 1; Do wn l 3. Check that the correct 7-bit FAS is present in the assumed TS 0 byte of the next frame. If either of the conditions in steps 2 or 3 are not met, a new search for frame alignment is initiated in the bit immediately following the second 7-bit FAS sequence check. This "hold-off" is done to ensure that new frame alignment PROPRIETARY AND CONFIDENTIAL 62 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 searches are done in the next bit position, modulo 512. This facilitates the discovery of the correct frame alignment, even in the presence of fixed timeslot data imitating the FAS. t, 20 07 01 These algorithms provide robust framing operation even in the presence of random bit errors: framing with algorithm #1 or #2 provides a 99.98% probability of finding frame alignment within 1 ms in the presence of 10-3 bit error rate and no mimic patterns. Th ur sd ay ,0 2A ug us Once frame alignment is found, the block sets the OOF indication low, indicates a change of frame alignment (if it occurred), and monitors the frame alignment signal, indicating errors occurring in the 7-bit FAS pattern and in bit 2 of NFAS frames, and indicating the debounced value of the Remote Alarm bit (bit 3 of NFAS frames). Using debounce, the Remote Alarm bit has <0.00001% probability of being falsely indicated in the presence of a 10-3 bit error rate. The block declares loss of frame alignment if 3 consecutive FASs have been received in error or, additionally, if bit 2 of NFAS frames has been in error for 3 consecutive occasions. In the presence of a random 10-3 bit error rate the frame loss criteria provides a mean time to falsely lose frame alignment of >12 minutes. cir o on The E1-FRMR can be forced to initiate a basic frame search at any time when any of the following conditions are met: the software re-frame bit in the E1-FRMR Frame Alignment Options register goes to logic 1; * the CRC Frame Find Block is unable to find CRC multiframe alignment; or * the CRC Frame Find Block accumulates excessive CRC evaluation errors ( 915 CRC errors in 1 second) and is enabled to force a re-frame under that condition. ra s ha d of bn ha * ab do u CRC Multiframe Alignment Procedure oa d ed by The E1-FRMR searches for CRC multiframe alignment by observing whether the International bits (bit 1 of TS 0) of NFAS frames follow the CRC multiframe alignment pattern. Multiframe alignment is declared if at least two valid CRC multiframe alignment signals are observed within 8 ms, with the time separating two alignment signals being a multiple of 2 ms Do wn l Once CRC multiframe alignment is found, the OOCMFV register bit is set to logic 0, and the E1-FRMR monitors the multiframe alignment signal, indicating errors occurring in the 6-bit MFAS pattern, errors occurring in the received CRC and the value of the FEBE bits (bit 1 of frames 13 and 15 of the multiframe). The E1-FRMR declares loss of CRC multiframe alignment if basic frame alignment is PROPRIETARY AND CONFIDENTIAL 63 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 lost. However, once CRC multiframe alignment is found, it cannot be lost due to errors in the 6-bit MFAS pattern. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 Under the CRC-to-non-CRC interworking algorithm, if the E1-FRMR can achieve basic frame alignment with respect to the incoming PCM data stream, but is unable to achieve CRC-4 multiframe alignment within the subsequent 400 ms, the distant end is assumed is assumed to be a non CRC-4 interface. The details of this algorithm are illustrated in the state diagram in Figure 8. PROPRIETARY AND CONFIDENTIAL 64 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - CRC Multiframe Alignment Algorithm :2 6: Figure 8 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 Out of Fram e us t, 20 3 consecutiv e FAS or NF AS errors; m anual refram e; or excessiv e C RC errors FAS_Find_1_Par FAS found NFAS_Find_Par NFAS found next fram e o cir bn ha FAS_Find_2_Par FAS found next fram e 8m s expire and NOT(400m s expire) Reset BF A to m ost recently found alignm ent CR CMFA_Par (Optional setting) Do wn l oa d ed CRC to CRC Interworking PROPRIETARY AND CONFIDENTIAL Start 8m s tim er BFA_Par CR CMFA_Par by CR C MFA ab do u BFA ra s ha d of 8m s expire Start 400m s tim er and 8m s tim er FAS not found next fram e on FAS not found next fram e FAS_Find_2 FAS found next fram e Th ur NFAS_Find NFAS found next fram e NFAS not found next fram e sd ay ,0 NFAS not found next fram e FAS found 2A ug FAS_Find_1 65 CRC to non-CRC Interworking 400m s expire PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 6: Out of Offline Frame :2 Out of Frame Yes NFAS_Find Yes FAS_Find_2 Yes BFA No CRC to CRC Interworking No No No Yes No Yes No Yes No No No No 20 t, us ug 2A sd ay FAS_Find_1_Par ur NFAS_Find_Par Th FAS_Find_2_Par o on BFA_Par No 07 FAS_Find_1 ,0 State 50 - E1-FRMR Framing States 01 Table 15 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 cir CRC to non-CRC Interworking No No No of bn ha The states of the primary basic framer and the parallel/offline framer in the E1-FRMR block at each stage of the CRC multiframe alignment algorithm are shown in Table 15. ab do u ra s ha d From an out of frame state, the E1-FRMR attempts to find basic frame alignment in accordance with the FAS/NFAS/FAS G.706 Basic Frame Alignment procedure outlined above. Upon achieving basic frame alignment, a 400 ms timer is started, as well as an 8 ms timer. If two CRC multiframe alignment signals separated by a multiple of 2 ms are observed before the 8 ms timer has expired, CRC multiframe alignment is declared. Do wn l oa d ed by If the 8 ms timer expires without achieving multiframe alignment, a new offline search for basic frame alignment is initiated. This search is performed in accordance with the Basic Frame Alignment procedure outlined above. However, this search does not immediately change the actual basic frame alignment of the system (i.e., PCM data continues to be processed in accordance with the first basic frame alignment found after an out of frame state while this frame alignment search occurs as a parallel operation). When a new basic frame alignment is found by this offline search, the 8 ms timer is restarted. If two CRC multiframe alignment signals separated by a multiple of PROPRIETARY AND CONFIDENTIAL 66 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 2 ms are observed before the 8 ms timer has expired, CRC multiframe alignment is declared and the basic frame alignment is set accordingly (i.e., the basic frame alignment is set to correspond to the frame alignment found by the parallel offline search, which is also the basic frame alignment corresponding to the newly found CRC multiframe alignment). sd ay ,0 2A ug us t, 20 Subsequent expirations of the 8 ms timer will likewise reinitiate a new search for basic frame alignment. If, however, the 400 ms timer expires at any time during this procedure, the E1-FRMR stops searching for CRC multiframe alignment and declares CRC-to-non-CRC interworking. In this mode, the E1-FRMR may be optionally set to either halt searching for CRC multiframe altogether, or may continue searching for CRC multiframe alignment using the established basic frame alignment. In either case, no further adjustments are made to the basic frame alignment, and no offline searches for basic frame alignment occur once CRC-to-non-CRC interworking is declared: it is assumed that the established basic frame alignment at this point is correct. Th ur AIS Detection bn ha cir o on When an unframed all-ones receive data stream is received, an AIS defect is indicated by setting the AISD bit to logic 1 when fewer than three zero bits are received in 512 consecutive bits or, optionally, in each of two consecutive periods of 512 bits. The AISD bit is reset to logic 0 when three or more zeros in 512 consecutive bits or in each of two consecutive periods of 512 bits. Finding frame alignment will also cause the AISD bit to be set to logic 0. d of Signaling Frame Alignment ab do u ra s ha Once the basic frame alignment has been found, the E1-FRMR searches for Channel Associated Signaling (CAS) multiframe alignment using the following G.732 compliant algorithm: signaling multiframe alignment is declared when at least one non-zero time slot 16 bit is observed to precede a time slot 16 containing the correct CAS alignment pattern, namely four zeros ("0000") in the first four bit positions of timeslot 16. Do wn l oa d ed by Once signaling multiframe alignment has been found, the E1-FRMR sets the OOSMFV bit of the E1-FRMR Framing Status register to logic 0, and monitors the signaling multiframe alignment signal, indicating errors occurring in the 4-bit pattern, and indicating the debounced value of the Remote Signaling Multiframe Alarm bit (bit 6 of timeslot 16 of frame 0 of the multiframe). Using debounce, the Remote Signaling Multiframe Alarm bit has < 0.00001% probability of being falsely indicated in the presence of a 10-3 bit error rate. PROPRIETARY AND CONFIDENTIAL 67 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 The block declares loss of CAS multiframe alignment if two consecutive CAS multiframe alignment signals have been received in error, or additionally, if all the bits in time slot 16 are logic 0 for 1 or 2 (selectable) CAS multiframes. Loss of CAS multiframe alignment is also declared if basic frame alignment has been lost. 20 National Bit Extraction 2A ug us t, The E1-FRMR extracts and assembles the submultiframe-aligned National bit codewords Sa4[1:4] , Sa5[1:4] , Sa6[1:4] , Sa7[1:4] and Sa8[1:4]. The corresponding register values are updated upon generation of the CRC submultiframe interrupt. ur sd ay ,0 This E1-FRMR also detects the V5.2 link ID signal, which is defined as the condition where 2 out of 3 Sa7 bits are zeroes. Upon reception of this Link ID signal, the V52LINKV bit of the E1-FRMR Framing Status register is set to logic 1. This bit is cleared to logic 0 when 2 out of 3 Sa7 bits are ones. on Th Alarm Integration ha cir o The OOF and the AIS defects are integrated, verifying that each condition has persisted for 104 ms ( 6 ms) before indicating the alarm condition. The alarm is removed when the condition has been absent for 104 ms ( 6 ms). ab do u ra s ha d of bn The AIS alarm algorithm accumulates the occurrences of AISD (AIS detection). The E1-FRMR counts the occurrences of AISD over a 4 ms interval and indicates a valid AIS is present when 13 or more AISD indications (of a possible 16) have been received. Each interval with a valid AIS presence indication increments an interval counter which declares AIS Alarm when 25 valid intervals have been accumulated. An interval with no valid AIS presence indication decrements the interval counter. The AIS Alarm declaration is removed when the counter reaches 0. This algorithm provides a 99.8% probability of declaring an AIS Alarm within 104 ms in the presence of a 10-3 mean bit error rate. Do wn l oa d ed by The Red alarm algorithm monitors occurrences of OOF over a 4 ms interval, indicating a valid OOF interval when one or more OOF indications occurred during the interval, and indicating a valid in frame (INF) interval when no OOF indication occurred for the entire interval. Each interval with a valid OOF indication increments an interval counter which declares Red Alarm when 25 valid intervals have been accumulated. An interval with valid INF indication decrements the interval counter; the Red Alarm declaration is removed when the counter reaches 0. This algorithm biases OOF occurrences, leading to declaration of Red alarm when intermittent loss of frame alignment occurs. PROPRIETARY AND CONFIDENTIAL 68 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER 50 T1 Inband Loopback Code Detector (IBCD) 6: 9.5 ISSUE 11 AM PMC-1970624 ,0 T1 Pulse Density Violation Detector (PDVD) ay 9.6 2A ug us t, 20 07 01 :2 The T1 Inband Loopback Code Detection function is provided by the IBCD block. This block detects the presence of either of two programmable INBAND LOOPBACK ACTIVATE and DEACTIVATE code sequences in either framed or unframed data streams. Each INBAND LOOPBACK code sequence is defined as the repetition of the programmed code in the PCM stream for at least 5.1 seconds. The code sequence detection and timing is compatible with the specifications defined in T1.403-1993, TA-TSY-000312, and TR-TSY-000303. LOOPBACK ACTIVATE and DEACTIVATE code indication is provided through internal register bits. An interrupt is generated to indicate when either code status has changed. cir o on Th ur sd The Pulse Density Violation Detection function is provided by the PDVD block. The block detects pulse density violations of the requirement that there be N ones in each and every time window of 8(N+1) data bits (where N can equal 1 through 23). The PDVD also detects periods of 16 consecutive zeros in the incoming data. Pulse density violation detection is provided through an internal register bit. An interrupt is generated to signal a 16 consecutive zero event, and/or a change of state on the pulse density violation indication. d Performance Monitor Counters (PMON) ha 9.7 of bn ha The PDVD block is available when the analog RXTIP and RXRING inputs are enabled (i.e., when the RUNI bit in the Receive Line Interface Configuration register is logic 0). Do wn l oa d ed by ab do u ra s The Performance Monitor Counters function is provided by the PMON block. The block accumulates CRC error events, Frame Synchronization bit error events, Line Code Violation events, and Out Of Frame events, or optionally, Change of Frame Alignment (COFA) events with saturating counters over consecutive intervals as defined by the period of the supplied transfer clock signal (typically 1 second). When the transfer clock signal is applied, the PMON transfers the counter values into holding registers and resets the counters to begin accumulating events for the interval. The counters are reset in such a manner that error events occurring during the reset are not missed. If the holding registers are not read between successive transfer clocks, an OVERRUN register bit is asserted. For T1, a line code violation is either a bipolar violation (only those not part of a zero substitution code for B8ZS-coded and HDB3 signals) or excessive zeros. Excessive zeros is a sequence of zeros greater than 15 bits long for an AMI-code PROPRIETARY AND CONFIDENTIAL 69 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 signal and greater than 7 bits long for a B8ZS-coded signals. The inclusion of excessive zeros in the line code violation count can be disabled. 07 01 :2 For E1, a line code violation is defined as a bipolar violation (BPV) for AMI-coded signals and is defined as a bipolar violation of the same polarity as the last bipolar violation for HDB3-coded signals. 2A T1 Bit Oriented Code Detector (RBOC) ,0 9.8 ug us t, 20 Generation of the transfer clock within the COMET chip is performed by writing to any counter register location or by writing to the Global PMON Update register. The holding register addresses are contiguous to facilitate faster polling operations. on Th ur sd ay The Bit Oriented Code detection function is provided by the RBOC block. This block detects the presence of 63 of the possible 64 bit oriented codes transmitted in the Facility Data Link channel in ESF framing format, as defined in ANSI T1.403-1993 and in TR-TSY-000194. The 64th code (111111) is similar to the DL FLAG sequence and is used by the RBOC to indicate no valid code received. bn ha cir o Bit oriented codes are received on the Facility Data Link channel as a 16-bit sequence consisting of 8 ones, a zero, 6 code bits, and a trailing zero (111111110xxxxxx0) which is repeated at least 10 times. The RBOC can be enabled to declare a received code valid if it has been observed for 8 out of 10 times or for 4 out of 5 times, as specified by the AVC bit in the control register. HDLC Receiver (RDLC) ab do u 9.9 ra s ha d of Valid BOC are indicated through an internal status register. The BOC bits are set to all ones (111111) if no valid code has been detected. An interrupt is generated to signal when a detected code has been validated, or optionally, when a valid code goes away (i.e. the BOC bits go to all ones). T1 ESF facility data link oa d * ed by The HDLC Receiver function is provided by the RDLC block. The RDLC is a microprocessor peripheral used to receive HDLC frames. Three RDLC blocks are provided for flexible extraction of standardized data links: T1DM data link * ISDN D-channel * E1 Common Channel Signaling data link Do wn l * PROPRIETARY AND CONFIDENTIAL 70 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER V5.1/V5.2 D-channel and C-channels. * E1 Sa-bit data link :2 6: * AM ISSUE 11 50 PMC-1970624 20 07 01 The RDLC detects the change from flag characters to the first byte of data, removes stuffed zeros on the incoming data stream, receives packet data, and calculates the CRC-CCITT frame check sequence (FCS). 2A ug us t, In the address matching mode, only those packets whose first data byte matches one of two programmable bytes or the universal address (all ones) are stored in the FIFO. The two least significant bits of the address comparison can be masked for LAPD SAPI matching. ur sd ay ,0 Received data is placed into a 128-byte FIFO buffer. An interrupt is generated when a programmable number of bytes are stored in the FIFO buffer. Other sources of interrupt are detection of the terminating flag sequence, abort sequence, or FIFO buffer overrun. bn T1 Alarm Integrator (ALMI) of 9.10 ha cir o on Th The Status Register contains bits which indicate the overrun or empty FIFO status, the interrupt status, and the occurrence of first flag or end of message bytes written into the FIFO. The Status Register also indicates the abort, flag, and end of message status of the data just read from the FIFO. On end of message, the Status Register indicates the FCS status and if the packet contained a non-integer number of bytes. ab do u ra s ha d The T1 Alarm Integration function is provided by the ALMI block. This block detects the presence of Yellow, Red, and AIS Carrier Fail Alarms (CFA) in SF, T1DM, SLC(R)96, or ESF formats. The alarm detection and integration is compatible with the specifications defined in Bell Pub 43801, TA-TSY-000278, TR-TSY-000008, ANSI T1.403-1993, and TR-TSY-000191. Alarm detection and validation for SLC(R)96 is handled the same as SF framing format. Do wn l oa d ed by The ALMI block declares the presence of Yellow alarm when the Yellow pattern has been received for 425 ms ( 50 ms); the Yellow alarm is removed when the Yellow pattern has been absent for 425 ms ( 50 ms). The presence of Red alarm is declared when an out-of-frame condition has been present for 2.55 sec ( 40 ms); the Red alarm is removed when the out-of-frame condition has been absent for 16.6 sec ( 500 ms). In T1DM framing format the Red alarm declaration criteria can be selected to be either 400 ms ( 100 ms) or 2.55 sec ( 40 ms); removal of the Red alarm in T1DM can be selected to be either 100 ms ( 50 ms) or 16.6 sec ( 500 ms). The presence of AIS alarm is declared when an out-of-frame condition and all-ones in the PCM data stream PROPRIETARY AND CONFIDENTIAL 71 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 have been present for 1.5 sec ( 100 ms); the AIS alarm is removed when the AIS condition has been absent for 16.8 sec ( 500 ms). 07 01 :2 CFA alarm detection algorithms operate in the presence of a random 10-3 bit error rate. 2A Receive Elastic Store (RX-ELST) ,0 9.11 ug us t, 20 The ALMI also indicates the presence or absence of the Yellow, Red, and AIS alarm signal conditions over 40 ms , 40 ms and 60 ms intervals, respectively, allowing an external microprocessor to integrate the alarm conditions via software with any user-specific algorithms. Alarm indication is provided through internal register bits. Th ur sd ay The Receive Elastic Store (RX-ELST) synchronizes incoming PCM frames to the local backplane clock, BRCLK. The frame data is buffered in a two-frame circular data buffer. Input data is written to the buffer using a write pointer and output data is read from the buffer using a read pointer. ha cir o on When the elastic store is being used, if the average frequency of the incoming data is greater than the average frequency of the backplane clock, the write pointer will catch up to the read pointer and the buffer will be filled. Under this condition a controlled slip will occur when the read pointer crosses the next frame boundary. The following frame of PCM data will be deleted. ra s ha d of bn If the average frequency of the incoming data is less than the average frequency of the backplane clock, the read pointer will catch up to the write pointer and the buffer will be empty. Under this condition a controlled slip will occur when the read pointer crosses the next frame boundary. The last frame which was read will be repeated. ab do u A slip operation is always performed on a frame boundary. Do wn l oa d ed by When the backplane timing is derived from the receive line data (i.e. BRCLK is an output), the elastic store can be bypassed to eliminate the two frame delay. In this configuration the elastic store can be used to measure frequency differences between the recovered line clock and another 1.544 MHz or 2.048 MHz clock applied to the BRCLK input. A typical example might be to measure the difference in frequency between two received streams (i.e. East-West frequency difference) by monitoring the number of SLIP occurrences of one direction with respect to the other. To allow for the extraction of signaling information in the PCM data channels, superframe identification is also passed through the RX-ELST. PROPRIETARY AND CONFIDENTIAL 72 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 Receive Jitter Attenuator (RJAT) 07 9.12 :2 6: 50 For payload conditioning, the RX-ELST may optionally insert a programmable idle code into all channels when the framer is out of frame synchronization. This code is set to all 1's when the RX-ELST is reset. us t, 20 The Receive Jitter Attenuator (RJAT) digital PLL attenuates the jitter present on the RXTIP/RXRING or RDAT inputs. The attenuation is only performed when the RJATBYP register bit is a logic 0. ,0 Signaling Extractor (SIGX) ay 9.13 2A ug The jitter characteristics of the Receive Jitter Attenuator (RJAT) are the same as the Transmit Jitter Attenuator (TJAT). on Th ur sd The Signaling Extraction (SIGX) block provides channel associated signaling (CAS) extraction from an E1 signaling multiframe or from SF and ESF T1 formats. With external logic the Signaling Extraction (SIGX) block extracts the nine bit signaling format from SLC(R)96 T1 formats. ra s ha d of bn ha cir o The SIGX block provides signaling bit extraction from the received data stream for T1 ESF, SF, SLC(R)96 and E1 framing formats. It selectively debounces the bits, and serializes the results onto the BRSIG output. Debouncing is performed on individual signaling bits. This BRSIG output is channel aligned with BRPCM output, and the signaling bits are repeated for the entire superframe, allowing downstream logic to reinsert signaling into any frame, as determined by system timing. The signaling data stream contains the A,B,C,D bits in the lower 4 channel bit locations (bits 5, 6, 7 and 8) in T1 ESF and E1 framing formats; in SF and SLC(R)96 formats the A and B bits are repeated in locations C and D (i.e. the signaling stream contains the bits ABAB for each channel). ed by ab do u The SIGX block contains three superframes worth of signal buffering to ensure that there is a greater than 95% probability that the signaling bits are frozen in the correct state for a 50% ones density out-of-frame condition, as specified in TR-TSY-000170 and BELL PUB 43801. With signaling debounce enabled, the per-channel signaling state must be in the same state for 2 superframes before appearing on the serial output stream. Do wn l oa d The SIGX block provides one superframe or signaling-multiframe of signal freezing on the occurrence of slips. When a slip event occurs, the SIGX freezes the output signaling for the entire superframe in which the slip occurred; the signaling is unfrozen when the next slip-free superframe occurs. PROPRIETARY AND CONFIDENTIAL 73 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 The SIGX also provides control over timeslot signaling bit fixing, data inversion and signaling debounce on a per-timeslot basis. 01 :2 The SIGX block also provides an interrupt to indicate a change of signaling state on a per channel basis. 07 Receive Per-channel Serial Controller (RPSC) 20 9.14 ug us t, The Receive Per-channel Serial Controller (RPSC) function is provided by a PCSC block. ay T1 Signaling Aligner (SIGA) sd 9.15 ,0 2A The RPSC allows data and signaling trunk conditioning to be applied independently on the receive stream on a per-channel basis. o T1 Basic Transmitter (XBAS) cir 9.16 on Th ur The T1 Signaling Aligner can be positioned before the T1 basic transmitter to provide superframe alignment of the signaling bits between the backplane and the transmit DS-1 stream. The signaling alignment block maintains signaling bit integrity across superframe boundaries. bn ha The T1 Basic Transmitter (XBAS) block generates the 1.544 Mbit/s T1 data stream according to SF, ESF, T1DM or SLC(R)96 formats. ed by ab do u ra s ha d of In concert with the Transmit Per-Channel Serial Controller (TPSC), the XBAS block provides per channel control of idle code substitution, data inversion (either all 8 bits, sign bit only or magnitude only), digital milliwatt substitution, and zero code suppression. Three types of zero code suppression (GTE, Bell and DDS) are supported and selected on a per channel basis to provide minimum ones density control. Robbed bit signaling control and selection of the signaling source are also performed on a per-channel basis. All channels can be forced into a trunk conditioning state (idle code substitution and signaling conditioning) by use of the Master Trunk Conditioning bit in the T1 XBAS Configuration Register. Do wn l oa d A data link is provided for ESF, T1DM and SLC(R)96 modes. The data link sources include bit oriented codes and HDLC messages. Support is provided for the transmission of framed or unframed Inband Code sequences and transmission of AIS or Yellow alarm signals for all formats. PCM output signals may be selected to conform to B8ZS or AMI line coding. PROPRIETARY AND CONFIDENTIAL 74 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 E1 Transmitter (E1-TRAN) 20 9.17 01 :2 6: 50 The transmitter can be disabled for framing via the FDIS bit in the Transmit Framing and Bypass Options register. When transmitting ESF formatted data, the framing bit, datalink bit, or the CRC-6 bit from the input PCM stream can be by-passed to the output PCM stream. 2A ug us t, The E1 Transmitter (E1-TRAN) generates a 2048 kbit/s data stream according to ITU-T recommendations, providing individual enables for frame generation, CRC multiframe generation, and channel associated signaling (CAS) multiframe generation. Th ur sd ay ,0 In concert with Transmit Per-Channel Serial Controller (TPSC), the E1-TRAN block provides per-timeslot control of idle code substitution, data inversion, digital milliwatt substitution, selection of the signaling source and CAS data. All timeslots can be forced into a trunk conditioning state (idle code substitution and signaling substitution) by use of the master trunk conditioning bit in the Configuration Register. ha cir o on Common Channel Signaling (CCS) is supported in time slot 16 either through the internal HDLC Transmitter (TDPR) and the Transmit Channel Insertion (TXCI) block. Support is provided for the transmission of AIS and the transmission of remote alarm (RAI) and remote multiframe alarm signals. ha d of bn The National Use bits (Sa-bits) can be sourced from the E1-TRAN National Bits Codeword registers as 4-bit codewords aligned to the submultiframe. Alternatively, the Sa-bits may individually carry data links sourced from the internal HDLC controllers, or may be passed transparently from the BTPCM input. ra s PCM output signals may be selected to conform to HDB3 or AMI line coding. Transmit Elastic Store (TX-ELST) ab do u 9.18 oa d ed by The Transmit Elastic Store (TX-ELST) provides the ability to decouple the line timing from the backplane timing. The TX-ELST is required whenever the BTCLK and TCLKO clocks are not traceable to a common source. The elastic store function is in effect (with a nominal one frame delay) when: Do wn l 1. BTCLK is an input (CMODE = 1) and the transmitter is loop timed to the receive recovered clock (PLLREF[1:0] = `b10, OCLKSEL1 = 0, OCLKSEL0 = 0). PROPRIETARY AND CONFIDENTIAL 75 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 2. BTCLK is an input (CMODE = 1) and the transmitter is clocked by TCLKI (OCLKSEL1 = 0, OCLKSEL0 = 1) or a jitter attenuated version of TCLKI (PLLREF[1:0] = `b11, OCLKSEL1 = 0, OCLKSEL0 = 0). 20 07 01 3. BTCLK is an output (CMODE = 0) referenced to the receive recovered clock (PLLREF[1:0] = `b10) and the transmitter is clocked by TCLKI (OCLKSEL1 = 0, OCLKSEL0 = 1). 2A ug us t, When the elastic store is being used, if the average frequency of the backplane data is greater than the average frequency of the line clock, the buffer will fill. Under this condition a controlled slip will occur upon the next frame boundary. The following frame of PCM data will be deleted. sd ay ,0 If the average frequency of the backplane data is less than the average frequency of the line clock, the buffer empty. Under this condition a controlled slip will occur upon the next frame boundary. The latest frame will be repeated. on Th ur A slip operation is always performed on a frame boundary. The TX-ELST is upstream of the frame overhead insertion; therefore, frame slips do not corrupt the frame alignment signal. ha Transmit Per-Channel Serial Controller (TPSC) bn 9.19 cir o When the line timing is derived from BTCLK or BTCLK is an output, the elastic store is bypassed to eliminate the two frame delay. ra s ha d of The Transmit Per-channel Serial Controller allows data and signaling trunk conditioning or idle code to be applied on the transmit DS-1 stream on a perchannel basis. It also allows per-channel control of zero code suppression, data inversion, and application of digital milliwatt. by ab do u The Transmit Per-channel Serial Controller function is provided by a Per-Channel Serial Controller (PCSC) block. The PCSC is a general purpose triple serializer. Data is sourced from three banks of thirty-two 8-bit registers, with each bank supporting a single serial output. oa d ed The TPSC interfaces directly to the E1-TRAN and T1-XBAS blocks to provide serial streams for signaling control, idle code data and PCM data control. Do wn l The registers are accessible from the P interface in an indirect address mode. The BUSY indication signal can be polled from an internal status register to check for completion of the current operation. PROPRIETARY AND CONFIDENTIAL 76 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER 50 T1 Inband Loopback Code Generator (XIBC) 6: 9.20 ISSUE 11 AM PMC-1970624 ug T1 Bit Oriented Code Generator (XBOC) 2A 9.21 us t, 20 07 01 :2 The T1 Inband Loopback Code Generator (XIBC) block generates a stream of inband loopback codes (IBC) to be inserted into a T1 data stream. The IBC stream consists of continuous repetitions of a specific code and can be either framed or unframed. When the XIBC is enabled to generate framed IBC, the framing bit overwrites the inband code pattern. The contents of the code and its length are programmable from 3 to 8 bits. The XIBC interfaces directly to the XBAS Basic Transmitter block. Th ur sd ay ,0 The T1 Bit Oriented Code Generator function is provided by the XBOC block. This block transmits 63 of the possible 64 bit oriented codes in the Facility Data Link channel in ESF framing format, as defined in ANSI T1.403-1989. The 64th code (111111) is similar to the HDLC Flag sequence and is used in the XBOC to disable transmission of any bit oriented codes. HDLC Transmitters of 9.22 bn ha cir o on Bit oriented codes are transmitted on the Facility Data Link channel as a 16-bit sequence consisting of 8 ones, a zero, 6 code bits, and a trailing zero (111111110xxxxxx0) which is repeated as long as the code is not 111111. The transmitted bit oriented codes have priority over any data transmitted on the FDL except for ESF Yellow Alarm. The code to be transmitted is programmed by writing the code register. ra s ha d The HDLC Transmit function is provided by the TDPR block. Three TDPR blocks are provided for flexible insertion of standardized data links: T1 ESF facility data link * T1DM data link * ISDN D-channel * E1 Common Channel Signaling data link oa d ed by ab do u * wn l * Do * V5.1/V5.2 D-channel and C-channels. E1 Sa-bit data link The TDPR is a general purpose HDLC transmitter. The TDPR is used under microprocessor control to transmit HDLC data frames. The TDPR performs all of PROPRIETARY AND CONFIDENTIAL 77 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 the data serialization, CRC generation, zero-bit stuffing, as well as flag, idle, and abort sequence insertion. Data to be transmitted is provided by writing to a transmit data register. Upon completion of the frames, a CRC-CCITT frame check sequence is transmitted, followed by flag sequences. If the transmit data register underflows, an abort sequence is automatically transmitted. ug us t, 20 When enabled, the TDPR continuously transmits the flag sequence (01111110) until data is ready to be transmitted. Data bytes to be transmitted are written into the Transmit Data Register. The TDPR performs a parallel-to-serial conversion of each data byte and transmits it using one of two procedures. o on Th ur sd ay ,0 2A The default procedure provides automatic transmission of data once a complete packet is written. All complete packets of data will be transmitted. After the last data byte of a packet, the CRC word (if CRC insertion has been enabled) and a flag, or just a flag (if CRC insertion has not been enabled) is transmitted. The TDPR then returns to the transmission of flag characters until the next packet is available for transmission. While working in this mode, the user must only be careful to avoid overfilling the FIFO; underruns cannot occur unless the packet is greater than 128 bytes long. The TDPR will force transmission if the FIFO is filled up regardless of whether or not the packet has been completely written into the FIFO. ha d of bn ha cir The second procedure transmits data only when the FIFO depth has reached a user configured upper threshold. The TDPR will continue to transmit data until the FIFO depth has fallen below the upper threshold and the transmission of the last packet with data above the upper threshold has completed. In this mode, the user must be careful to avoid overruns and underruns. An interrupt can be generated once the FIFO depth has fallen below a user configured lower threshold as an indicator for the user to write more data. ab do u ra s If there are more than five consecutive ones in the raw transmit data or in the CRC data, a zero is stuffed into the serial data output. This prevents the unintentional transmission of flag or abort characters. T1 Automatic Performance Report Generation Do wn l 9.23 oa d ed by Abort characters can be continuously transmitted at any time by setting a control bit. During transmission, an underrun situation can occur if data is not written to the Transmit Data Register before the previous byte of a packet currently being transmitted has been depleted. In this case, an abort sequence is transmitted, and the controlling processor is notified via the UDR signal. In compliance with the ANSI T1.231, T1.403 and T1.408 standards, a performance report is generated each second for T1 ESF applications. The PROPRIETARY AND CONFIDENTIAL 78 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 report conforms to the HDLC protocol and is inserted into the ESF facility data link. 20 07 01 :2 The performance report can only be transmitted if TDPR #1 is configured to insert the ESF Facility Data Link and the PREN bit of the TDPR #1 Configuration register is logic 1. The performance report takes precedence over incompletely written packets, but it does not pre-empt packets already being transmitted. ug Pulse Density Enforcer (XPDE) 2A 9.24 us t, See the Operation section for details on the performance report encoding. ay ,0 The Pulse Density Enforcer function is provided by the XPDE block. Pulse density enforcement is enabled by a register bit within the XPDE. ha Pseudo Random Pattern Generation and Detection bn 9.25 cir o on Th ur sd This block monitors the digital output of the transmitter and detects when the stream is about to violate the ANSI T1.403 12.5% pulse density rule over a moving 192-bit window. If a density violation is detected, the block can be enabled to insert a logic 1 into the digital stream to ensure the resultant output no longer violates the pulse density requirement. When the XPDE is disabled from inserting logic 1s, the digital stream from the transmitter is passed through unaltered. ra s ha d of The Pseudo Random Sequence Generator/Processor (PRGD) is a software programmable test pattern generator, receiver and analyzer. Two types of test patterns (pseudo random and repetitive) conform to ITU-T O.151, O.152 and O.153 standards. ab do u The PRGD can be programmed to generate pseudo random patterns with lengths up to 32 bits or any user programmable bit pattern from 1 to 32 bits in length. In addition, the PRGD can insert single bit errors or a bit error rate between 10-1 to 10-7. Do wn l oa d ed by The PRGD can be programmed to check for the generated pseudo random pattern. The PRGD can perform an auto synchronization to the expected pattern and accumulates the total number of bits received and the total number of bit errors in two 32-bit counters. The counters accumulate either over intervals defined by writes to the Pattern Detector registers or upon writes to the Global PMON Update Register. When an accumulation is forced, the holding registers are updated, and the counters reset to begin accumulating for the next interval. The counters are reset in such a way that no events are missed. The data is then available in the holding registers until the next accumulation. PROPRIETARY AND CONFIDENTIAL 79 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER 50 Transmit Jitter Attenuator (TJAT) 6: 9.26 ISSUE 11 AM PMC-1970624 us t, 20 07 01 :2 The Transmit Jitter Attenuation function is provided by a digital phase lock loop and 80-bit deep FIFO. The TJAT receives jittery, dual-rail data in NRZ format on two separate inputs, which allows bipolar violations to pass through the block uncorrected. The incoming data streams are stored in a FIFO timed to the transmit clock (either BTCLK or the recovered clock). The respective input data emerges from the FIFO timed to the jitter attenuated clock (TCLKO) referenced to either TCLKI, BTCLK, or the recovered clock. cir o on Th ur sd ay ,0 2A ug The jitter attenuator generates the jitter-free 1.544 MHz or 2.048 MHz TCLKO output transmit clock by adjusting TCLKO's phase in 1/96 UI increments to minimize the phase difference between the generated TCLKO and input data clock to TJAT (either BTCLK or the recovered clock). Jitter fluctuations in the phase of the input data clock are attenuated by the phase-locked loop within TJAT so that the frequency of TCLKO is equal to the average frequency of the input data clock. For T1 applications, to best fit the jitter attenuation transfer function recommended by TR 62411, phase fluctuations with a jitter frequency above 5.7 Hz are attenuated by 6 dB per octave of jitter frequency. Wandering phase fluctuations with frequencies below 5.7 Hz are tracked by the generated TCLKO. In E1 applications, the corner frequency is 7.6 Hz. To provide a smooth flow of data out of TJAT, TCLKO is used to read data out of the FIFO. d of bn ha If the FIFO read pointer (timed to TCLKO) comes within one bit of the write pointer (timed to the input data clock, BTCLK or RSYNC), TJAT will track the jitter of the input clock. This permits the phase jitter to pass through unattenuated, inhibiting the loss of data. ra s ha Jitter Characteristics Do wn l oa d ed by ab do u The TJAT Block provides excellent jitter tolerance and jitter attenuation while generating minimal residual jitter. It can accommodate up to 61 UIpp of input jitter at jitter frequencies above 5.7 Hz (7.6 Hz for E1). For jitter frequencies below 5.7 Hz (7.6 Hz for E1), more correctly called wander, the tolerance increases 20 dB per decade. In most applications the TJAT Block will limit jitter tolerance at lower jitter frequencies only. For high frequency jitter, above 10 kHz for example, other factors such as clock and data recovery circuitry may limit jitter tolerance and must be considered. For low frequency wander, below 10 Hz for example, other factors such as slip buffer hysteresis may limit wander tolerance and must be considered. The TJAT block meets the stringent low frequency jitter tolerance requirements of AT&T TR 62411 and thus allows compliance with this standard and the other less stringent jitter tolerance standards cited in the references. PROPRIETARY AND CONFIDENTIAL 80 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 The corner frequency in the jitter transfer response can be altered through programming. sd ay ,0 2A ug us t, 20 07 01 :2 TJAT exhibits negligible jitter gain for jitter frequencies below 5.7 Hz (7.6 Hz for E1), and attenuates jitter at frequencies above 5.7 Hz (7.6 Hz for E1) by 20 dB per decade. In most applications, the TJAT block will determine jitter attenuation for higher jitter frequencies only. Wander, below 10 Hz for example, will essentially be passed unattenuated through TJAT. Jitter, above 10 Hz for example, will be attenuated as specified, however, outgoing jitter may be dominated by the generated residual jitter in cases where incoming jitter is insignificant. This generated residual jitter is directly related to the use of a 1/96 UI phase adjustment quantum. TJAT meets the jitter attenuation requirements of AT&T TR 62411. The block allows the implied jitter attenuation requirements for a TE or NT1 given in ANSI Standard T1.408, and the implied jitter attenuation requirements for a type II customer interface given in ANSI T1.403 to be met. Th ur Jitter Tolerance Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Jitter tolerance is the maximum input phase jitter at a given jitter frequency that a device can accept without exceeding its linear operating range, or corrupting data. For TJAT, the input jitter tolerance is 61 Unit Intervals peak-to-peak (UIpp) with a worst case frequency offset of 354 Hz. It is 80 UIpp with no frequency offset. The frequency offset is the difference between the frequency of XCLK and that of the input data clock. Values above 2 kHz in the below graph are based on simulation results. PROPRIETARY AND CONFIDENTIAL 81 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - TJAT Jitter Tolerance 6: Figure 9 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 100 JAT MIN.TOLER ANCE 61 ug us t, 20 10 2A 1.0 ,0 JITTER AMPLITUDE, UI pp 07 28 0.4 unacceptable on 10 1 100 1k 10k 100k o 0.01 Th ur sd ay 0.1 acceptable bn ha cir JITTER FREQUENCY, Hz Do wn l oa d ed by ab do u ra s ha d of The accuracy of the XCLK frequency and that of the TJAT PLL reference input clock used to generate the jitter-free TCLKO output have an effect on the minimum jitter tolerance. Given that the TJAT PLL reference clock accuracy can be 200 Hz and that the XCLK input accuracy can be 100 ppm, the minimum jitter tolerance for various differences between the frequency of PLL reference clock and XCLK are shown in Figure 10. PROPRIETARY AND CONFIDENTIAL 82 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - TJAT Minimum Jitter Tolerance vs. XCLK Accuracy 6: Figure 10 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 70 66 20 65 68 us t, JAT MIN. JITTER TOLERANCE, 60 UI pp ,0 2A ug 61 Th ur sd ay 55 MAX. FREQUENCY 100 OFFSET cir 0 250 32 300 354 100 Hz , ppm ha XCLK ACCURACY o on 200 of bn Jitter Transfer Do wn l oa d ed by ab do u ra s ha d For T1 applications, the output jitter for jitter frequencies from 0 to 5.7 Hz (7.6 Hz for E1) is no more than 0.1 dB greater than the input jitter, excluding residual jitter. Jitter frequencies above 5.7 Hz (7.6 Hz for E1) are attenuated at a level of 6 dB per octave, as shown in Figure 11. PROPRIETARY AND CONFIDENTIAL 83 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - TJAT Jitter Transfer 6: Figure 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 -10 43802 max us t, 20 JITTER -20 GAIN dB -30 62411 max 62411 min 07 01 :2 0 2A ug JAT response sd ay ,0 -40 5.7 10 100 Th 1 ur -50 1k 10k cir o on JITTER FREQUENCY Hz bn ha T1 ha d of In the non-attenuating mode, when the FIFO is within one UI of overrunning or under running, the tracking range is 1.48 MHz to 1.608 MHz. ab do u ra s The guaranteed linear operating range for the jittered input clock is 1.544 MHz 200 Hz with worst case jitter (61 UIpp), and maximum system clock frequency offset ( 100 ppm). The nominal range is 1.544 MHz 963 Hz with no jitter or system clock frequency offset. by E1 oa d ed In the non-attenuating mode, when the FIFO is within one UI of overrunning or under running, the tracking range is 2.13 MHz to 1.97 MHz. Do wn l The guaranteed linear operating range for the jittered input clock is 2.048 MHz 300 Hz with worst case jitter (61 UIpp), and maximum system clock frequency offset ( 100 ppm). The nominal range is 2.048 MHz 1277 Hz with no jitter or system clock frequency offset. PROPRIETARY AND CONFIDENTIAL 84 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 Jitter Generation 20 Timing Options (TOPS) t, 9.27 07 01 :2 In the absence of input jitter, the output jitter shall be less than 0.025 UIpp. This complies with the AT&T TR 62411 requirement of less than 0.025 UIpp of jitter generation. ,0 Line Transmitter ay 9.28 2A ug us The Timing Options block provides a means of selecting the source of the reference signal for the transmit digital PLL and the clock source used to derive the output TCLKO signal. o on Th ur sd The line transmitter generates Alternate Mark Inversion (AMI) transmit pulses suitable for use in the DSX-1 (short haul T1), short haul E1, long haul T1 and long haul E1 environments. The voltage pulses are produced by applying a current to a known termination (termination resistor plus line impedance). The use of current (instead of a voltage driver) simplifies transmit Input Return Loss (IRL), transmit short circuit protection (none needed) and transmit tri-stating. ha d of bn ha cir The output pulse shape is synthesized digitally with current digital-to-analog (DAC) converters which produce 24 samples per symbol. The current DAC's produce differential bipolar outputs that directly drive the TXTIP[1:0] and TXRING[1:0] pins. The current output is applied to a terminating resistor (optional) and line-coupling transformer in a differential manner, which when viewed from the line side of the transformer produce the output pulses at the required levels and insures a small positive to negative pulse imbalance. oa d ed by ab do u ra s The pulse shape is user programmable. For T1 short haul, the cable length between the TLONG and the cross-connect (where the pulse template specifications are given) greatly affects the resulting pulse shapes. Hence, the data applied to the converter must account for different cable lengths. For CEPT E1 applications the pulse template is specified at the transmitter, thus only one setting is required. For T1 long haul with a LBO of 7.5 dB the previous bits effect what the transmitter must drive to compensate for inter-symbol interference; for LBO's of 15 dB or 22.5 dB the previous 3 or 4 bits effect what the transmitter must send out. Do wn l Refer to the Operation section for details on creating the synthesized pulse shape. PROPRIETARY AND CONFIDENTIAL 85 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER 50 Backplane Receive Interface (BRIF) 6: 9.29 ISSUE 11 AM PMC-1970624 07 01 :2 The Backplane Receive Interface allows data to be presented to a backplane in either a 1.544 Mbit/s, 2.048 Mbit/s, 4.096 Mbit/s, 8.192 Mbit/s or sub-rate NxDS0 serial stream. ug us t, 20 All receive backplane signals are synchronous to BRCLK. BRCLK may be an output, in which case it is a jitter attenuated version of the recovered clock. If BRCLK is an input, it clocks the output of the frame slip buffer; therefore, it must be plesiochronous to the recovered clock. o on Th ur sd ay ,0 2A When configured to provide a 1.544 Mbit/s data rate, the block generates the output data stream on the BRPCM pin containing 24 channel bytes of data followed by a single bit containing the framing bit or parity over the 24 channels. The BRSIG output pin contains 24 bytes of signaling nibble data located in the least significant nibble of each byte followed by a single bit position representing the "place holder" for the framing bit or parity over the 24 channels. The framing alignment indication on the BRFP pin indicates the first bit of the 193-bit frame (or, optionally, the first bit of every second frame, the first bit of the first frame of the superframe, or every second superframe). When BRFP is an input, the data read from the frame slip buffer is aligned to it. ab do u ra s ha d of bn ha cir In T1 mode, when configured to provide a 2.048 Mbit/s data rate, the block internally gaps the 2.048 MHz rate backplane clock to provide a serial PCM data on the BRPCM pin containing three channel bytes of data followed by one unused byte (can be logic 0 or logic 1). The signaling on the BRSIG pin is aligned to the least significant nibble of the associated channel on BRPCM. The frame alignment indication is provided on the BRFP pin, going high for one BRCLK cycle during the first bit of the unused byte, indicating the next data byte is the first channel of the frame, or the first channel of the first frame of the superframe. Alternatively, the PCM and signaling can be arranged in 24 contiguous timeslots, starting at the timeslot indicated by the BRFP pulse. Do wn l oa d ed by In E1 mode, the 2.048 Mbit/s data stream consumes all timeslots of BRPCM. The BRSIG output pin present 30 bytes of signaling nibble data located in the least significant nibble of each byte. The framing alignment indication on the BRFP output can be configured to indicate the first bit of each 256-bit frame, the first bit of every other 256-bit frame, the first bit of the first frame of the CRC multiframe, the first bit of the first frame of the signaling multiframe or all overhead bits. If BRFP is configured as an input, the BRPCM and BRSIG can be forced to an specific alignment provided the elastic store is used (the RXELSTBYP register bit is logic 0). When configured for NxDS0 operation, no output clock edges are generated during the framing bit positions and idle channels. PROPRIETARY AND CONFIDENTIAL 86 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 As a programming option, the data stream bit and timeslot alignment relative to BRFP can be modified for Concentration Highway Interface (CHI) applications. 20 Backplane Transmit Interface (BTIF) t, 9.30 07 01 :2 When configured for a multiplexed backplane, the two or four sets of PCM and signaling streams are byte-interleaved into a 4.096 Mbit/s or 8.192 Mbit/s serial stream. 2A ug us The Backplane Transmit Interface allows data to be taken from a backplane in either a 1.544 Mbit/s, 2.048 Mbit/s, 4.096 Mbit/s, 8.192 Mbit/s or sub-rate NxDS0 serial stream. cir o on Th ur sd ay ,0 When configured to receive a 1.544 Mbit/s data rate stream, the input data stream on the BTPCM pin to is expected to contain 24 channel bytes of data followed by a single bit location for the framing bit or optional parity over the previous 24 channels. The BTSIG input pin must contain 24 bytes of signaling nibble data located in the least significant nibble of each byte followed by a single bit position for the framing bit or optional parity over the previous frame. The framing alignment indication on the BTFP input must indicate the framing bit position of the 193-bit frame (or, optionally, the framing bit position of the first frame of the superframe). ra s ha d of bn ha In T1 mode, when configured to provide a 2.048 Mbit/s data rate, the block expects serial PCM data on the BTPCM pin to contain three channel bytes of data followed by one unused byte. The signaling on the BTSIG pin must be aligned to the least significant nibble of the associated channel on BTPCM. The frame alignment indication is expected on the BTFP pin, going to high during the first bit of the unused byte, indicating the next data byte is the first channel of the frame. Alternatively, the PCM and signaling can be arranged in 24 contiguous timeslots, starting at the timeslot indicated by the BTFP pulse. ed by ab do u In E1 mode, the 2.048 Mbit/s data stream consumes all timeslots of BRPCM. The BTSIG input presents 30 bytes of signaling nibble data located in the least significant nibble of each timeslot. The framing alignment indication on the BTFP pin can be configured to indicate the first bit of each 256-bit frame or the first bit of the first frame of the CRC multiframe and signaling multiframes. Do wn l oa d BTCLK can be configured as an output, in which case, BTCLK is generated from TCLKO. When configured for NxDS0 operation, no output clock edges are generated during the framing bit positions and idle channels. BTFP can be configured as an output, in which case, the COMET dictates the frame alignment. PROPRIETARY AND CONFIDENTIAL 87 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 As a programming option, the data stream bit and timeslot alignment relative to BTFP can be modified for Concentration Highway Interface (CHI) applications. 07 01 :2 When configured for a multiplexed backplane, one of two or four sets of PCM and signaling streams are extracted from the byte-interleaved 4.096 Mbit/s or 8.192 Mbit/s serial stream. t, 20 9.31 JTAG Test Access Port ay Microprocessor Interface (MPIF) sd 9.32 ,0 2A ug us The JTAG Test Access Port block provides JTAG support for boundary scan. The standard JTAG EXTEST, SAMPLE, BYPASS, IDCODE and STCTEST instructions are supported. The COMET revision E identification code is 443510CD hexadecimal. The revision F code is 543510CD. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur The Microprocessor Interface allows the COMET to be configured, controlled and monitored via internal registers. PROPRIETARY AND CONFIDENTIAL 88 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 REGISTER DESCRIPTION 10.1 Normal Mode Register Memory Map 01 Register 000H Global Configuration 001H Clock Monitor 002H Receive Options 003H Receive Line Interface Configuration 004H Transmit Line Interface Configuration 005H Transmit Framing and Bypass Options 006H Transmit Timing Options 007H Interrupt Source #1 008H Interrupt Source #2 009H Interrupt Source #3 00AH Master Diagnostics 00BH Master Test 00CH Analog Diagnostics 00DH Revision/Chip ID/Global PMON Update 010H us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 011H Reset PRGD Positioning/Control and HDLC Control ab do u 00FH t, Addr 00EH CDRC Configuration CDRC Interrupt Enable CDRC Interrupt Status 013H CDRC Alternate Loss of Signal 014H RJAT Interrupt Status oa d ed 012H wn l Do 07 - Normal Mode Register Memory Map 20 Table 16 :2 6: 10 015H RJAT Reference Clock Divisor (N1) Control 016H RJAT Output Clock Divisor (N2) Control 017H RJAT Configuration PROPRIETARY AND CONFIDENTIAL 89 PM4351 COMET STANDARD PRODUCT DATA SHEET Register 018H TJAT Interrupt Status 019H TJAT Reference Clock Divisor (N1) Control 01AH TJAT Output Clock Divisor (N2) Control 01BH TJAT Configuration 01CH RX-ELST Configuration 01DH RX-ELST Interrupt Enable/Status 01EH RX-ELST Idle Code 01FH RX-ELST Reserved 020H TX-ELST Configuration 021H TX-ELST Interrupt Enable/Status 022H-023H TX-ELST Reserved 024H-027H Reserved 028H RXCE Receive Data Link 1 Control 029H RXCE Receive Data Link 1 Bit Select 02AH RXCE Receive Data Link 2 Control 02BH RXCE Receive Data Link 2 Bit Select 02CH RXCE Receive Data Link 3 Control 02DH RXCE Receive Data Link 3 Bit Select 02EH-02FH RXCE Reserved 032H 6: :2 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 033H BRIF Receive Backplane Configuration BRIF Receive Backplane Frame Pulse Configuration ab do u 031H 50 Addr 030H BRIF Receive Backplane Parity/F-Bit Configuration BRIF Receive Backplane Time Slot Offset BRIF Receive Backplane Bit Offset 035H-037H BRIF Receive Backplane Reserved 038H TXCI Transmit Data Link 1 Control 039H TXCI Transmit Data Link 1 Bit Select 03AH TXCI Transmit Data Link 2 Control oa d ed 034H wn l Do COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 01 PMC-1970624 PROPRIETARY AND CONFIDENTIAL 90 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Register 03BH TXCI Transmit Data Link 2 Bit Select 03CH TXCI Transmit Data Link 3 Control 03DH TXCI Transmit Data Link 3 Bit Select 03EH-03FH TXCI Reserved 040H BTIF Transmit Backplane Configuration 041H BTIF Transmit Backplane Frame Pulse Configuration 042H BTIF Transmit Backplane Parity Configuration and Status 043H BTIF Transmit Backplane Time Slot Offset 044H BTIF Transmit Backplane Bit Offset Register 045H BTIF Transmit Backplane Reserved 046H BTIF Transmit Backplane Reserved 047H BTIF Transmit Backplane Reserved 048H T1 FRMR Configuration 049H T1 FRMR Interrupt Enable 04AH T1 FRMR Interrupt Status 04BH Reserved 04CH IBCD Configuration 04DH IBCD Interrupt Enable/Status 04EH IBCD Activate Code 051H 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s SIGX Configuration/Change of Signaling State SIGX P Access Status/Change of Signaling State SIGX Channel Indirect Address/Control/ Change of Signaling State 053H SIGX Channel Indirect Data Buffer/Change of Signaling State 054H T1 XBAS Configuration wn l oa d ed by 052H IBCD Deactivate Code ab do u 050H 50 Addr 04FH Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 055H T1 XBAS Alarm Transmit 056H T1 XIBC Control 057H T1 XIBC Loopback Code PROPRIETARY AND CONFIDENTIAL 91 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Register 058H PMON Interrupt Enable/Status 059H PMON Framing Bit Error Count 05AH PMON OOF/COFA/Far End Block Error Count (LSB) 05BH PMON OOF/COFA/Far End Block Error Count (MSB) 05CH PMON Bit Error/CRCE Count (LSB) 05DH PMON Bit Error/CRCE Count (MSB) 05EH PMON LCV Count (LSB) 05FH PMON LCV Count (MSB) 060H T1 ALMI Configuration 061H T1 ALMI Interrupt Enable 062H T1 ALMI Interrupt Status 063H T1 ALMI Alarm Detection Status 064H T1 PDVD Reserved 065H T1 PDVD Interrupt Enable/Status 066H T1 XBOC Reserved 067H T1 XBOC Code 068H T1 XPDE Reserved 069H T1 XPDE Interrupt Enable/Status 06AH T1 RBOC Enable 06DH 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 06EH T1 RBOC Code Status TPSC Configuration ab do u 06CH 50 Addr 06BH TPSC P Access Status TPSC Channel Indirect Address/Control TPSC Channel Indirect Data Buffer 070H RPSC Configuration 071H RPSC P Access Status 072H RPSC Channel Indirect Address/Control 073H RPSC Channel Indirect Data Buffer oa d ed 06FH wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PROPRIETARY AND CONFIDENTIAL 92 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Register 074H-077H Reserved 078H T1 APRM Configuration/Control 079H T1 APRM Manual Load 07AH T1 APRM Interrupt Status 07BH T1 APRM One Second Content Octet 2 07CH T1 APRM One Second Content Octet 3 07DH T1 APRM One Second Content Octet 4 07EH T1 APRM One Second Content MSB (Octet 5) 07FH T1 APRM One Second Content LSB (Octet 6) 080H E1 TRAN Configuration 081H E1 TRAN Transmit Alarm/Diagnostic Control 082H E1 TRAN International Control 083H E1 TRAN Extra Bits Control 084H E1 TRAN Interrupt Enable 085H E1 TRAN Interrupt Status 086H E1 TRAN National Bit Codeword Select 087H E1 TRAN National Bit Codeword 088H-08BH Reserved 08CH T1 FRMR Reserved 08FH 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 090H T1 FRMR Reserved Reserved ab do u 08EH 50 Addr 08DH Reserved E1 FRMR Frame Alignment Options E1 FRMR Maintenance Mode Options 092H E1 FRMR Framing Status Interrupt Enable 093H E1 FRMR Maintenance/Alarm Status Interrupt Enable 094H E1 FRMR Framing Status Interrupt Indication 095H E1 FRMR Maintenance/Alarm Status Interrupt Indication oa d ed 091H wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PROPRIETARY AND CONFIDENTIAL 93 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Register 096H E1 FRMR Framing Status 097H E1 FRMR Maintenance/Alarm Status 098H E1 FRMR International/National Bits 099H E1 FRMR CRC Error Count - LSB 09AH E1 FRMR CRC Error Count - MSB 09BH E1 FRMR National Bit Codeword Interrupt Enables 09CH E1 FRMR National Bit Codeword Interrupts 09DH E1 FRMR National Bit Codewords 09EH E1 FRMR Frame Pulse/Alarm Interrupt Enables 09FH E1 FRMR Frame Pulse/Alarm Interrupt 0A0H-0A7H Reserved 0A8H TDPR #1 Configuration 0A9H TDPR #1 Upper Transmit Threshold 0AAH TDPR #1 Lower Transmit Threshold 0ABH TDPR #1 Interrupt Enable 0ACH TDPR #1 Interrupt Status/UDR Clear 0ADH TDPR #1 Transmit Data 0AEH Reserved 0AFH Reserved 0B2H 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 0B3H TDPR #2 Configuration TDPR #2 Upper Transmit Threshold ab do u 0B1H 50 Addr 0B0H TDPR #2 Lower Transmit Threshold TDPR #2 Interrupt Enable TDPR #2 Interrupt Status/UDR Clear 0B5H TDPR #2 Transmit Data 0B6H Reserved 0B7H Reserved 0B8H TDPR #3 Configuration oa d ed 0B4H wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PROPRIETARY AND CONFIDENTIAL 94 PM4351 COMET STANDARD PRODUCT DATA SHEET Register 0B9H TDPR #3 Upper Transmit Threshold 0BAH TDPR #3 Lower Transmit Threshold 0BBH TDPR #3 Interrupt Enable 0BCH TDPR #3 Interrupt Status/UDR Clear 0BDH TDPR #3 Transmit Data 0BEH Reserved 0BFH Reserved 0C0H RDLC #1 Configuration 0C1H RDLC #1 Interrupt Control 0C2H RDLC #1 Status 0C3H RDLC #1 Data 0C4H RDLC #1 Primary Address Match 0C5H RDLC #1 Secondary Address Match 0C6H Reserved 0C7H Reserved 0C8H RDLC #2 Configuration 0C9H RDLC #2 Interrupt Control 0CAH RDLC #2 Status 0CBH RDLC #2 Data 0CEH RDLC #2 Secondary Address Match Reserved Reserved RDLC #3 Configuration 0D1H RDLC #3 Interrupt Control 0D2H RDLC #3 Status 0D3H RDLC #3 Data 0D4H RDLC #3 Primary Address Match wn l oa d ed 0D0H PROPRIETARY AND CONFIDENTIAL 6: :2 01 07 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 0CFH RDLC #2 Primary Address Match ab do u 0CDH 50 Addr 0CCH Do COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 20 PMC-1970624 95 PM4351 COMET STANDARD PRODUCT DATA SHEET Register 0D5H RDLC #3 Secondary Address Match 0D6H CSU Configuration 0D7H CSU Reserved 0D8H RLPS Indirect Data Register 0D9H RLPS Indirect Data Register 0DAH RLPS Indirect Data Register 0DBH RLPS Indirect Data Register 0DCH RLPS Equalizer Voltage Reference 0DDH-0DFH RLPS Reserved 0E0H PRGD Control 0E1H PRGD Interrupt Enable/Status 0E2H PRGD Shift Register Length 0E3H PRGD Tap 0E4H PRGD Error Insertion 0E5H PRGD Reserved 0E6H PRGD Reserved 0E7H PRGD Reserved 0E8H PRGD Pattern Insertion #1 0E9H PRGD Pattern Insertion #2 0ECH 6: 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s by 0EDH PRGD Pattern Insertion #3 PRGD Pattern Insertion #4 ab do u 0EBH 50 Addr 0EAH PRGD Pattern Detector #1 PRGD Pattern Detector #2 PRGD Pattern Detector #3 0EFH PRGD Pattern Detector #4 0F0H XLPG Line Driver Configuration 0F1H XLPG Control/Status 0F2H XLPG Pulse Waveform Storage Write Address oa d ed 0EEH wn l Do COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 :2 PMC-1970624 PROPRIETARY AND CONFIDENTIAL 96 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Register 0F3H XLPG Pulse Waveform Storage Data 0F4H XLPG Analog Test Positive Control 0F5H XLPG Analog Test Negative Control 0F6H XLPG Fuse Data Select 0F7H XLPG Reserved 0F8H RLPS Configuration and Status 0F9H RLPS ALOS Detection/Clearance Threshold 0FAH RLPS ALOS Detection Period 0FBH RLPS ALOS Clearance Period 0FCH RLPS Equalization Indirect Address 0FDH RLPS Equalization Read/WriteB Select 0FEH RLPS Equalizer Loop Status and Control 0FFH RLPS Equalizer Configuration 100H-1FFH Reserved for Test Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 Addr PROPRIETARY AND CONFIDENTIAL 97 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER NORMAL MODE REGISTER DESCRIPTION :2 6: 11 50 AM PMC-1970624 20 07 01 Normal mode registers are used to configure and monitor the operation of the COMET. Normal mode registers (as opposed to test mode registers) are selected when A[8] is low. us t, Notes on Normal Mode Register Bits: 2A ug 1. Writing values into unused register bits has no effect. Reading back unused bits can produce either a logic 1 or a logic 0; hence, unused register bits should be masked off by software when read. ur sd ay ,0 2. All configuration bits that can be written into can also be read back. This allows the processor controlling the COMET to determine the programming state of the chip. on Th 3. Writeable normal mode register bits are cleared to zero upon reset unless otherwise noted. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o 4. Writing into read-only normal mode register bit locations does not affect COMET operation unless otherwise noted. PROPRIETARY AND CONFIDENTIAL 98 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W PIO_OE 1 Bit 6 R/W PIO 0 Bit 5 R/W IBCD_IDLE 0 Bit 4 R/W RSYNC_ALOSB 0 Bit 3 R/W OOSMFAIS 0 Bit 2 R/W TRKEN Bit 1 R/W RXMTKC Bit 0 R/W E1/T1B :2 Type 2A ug us t, 20 07 01 Bit 6: Register 000H: Global Configuration 0 sd ay ,0 0 Th ur PIO_OE: 0 cir o on The programmable I/O output enable, PIO_OE, bit controls the PIO pin. When PIO_OE is logic 1, the PIO pin is configured as an output and driven by the COMET. When PIO_OE is logic 0, the PIO pin is configured as an input. Upon reset, the PIO pin is configured as an output. ha PIO: ab do u OOSMFAIS: ra s ha d of bn The programmable I/O, PIO, bit controls/reflects the state of the PIO pin. When the PIO pin is configured as an output, the PIO bit controls the state of the PIO pin. When the PIO pin is configured as an input, the PIO bit reflects the state of the PIO pin. Upon reset, the PIO pin has an output value of logic 0. ed by In E1 mode, this bit controls the receive backplane signaling trunk conditioning in an out of signaling multiframe condition. If OOSMFAIS is set to a logic 0, an OOSMF indication from the E1-FRMR does not affect the BRSIG output. When OOSMFAIS is a logic 1, an OOSMF indication from the E1-FRMR will cause the BRSIG output to be set to all 1's. Do wn l oa d RSYNC_ALOSB: The RSYNC_ALOSB bit controls the source of the loss of signal condition used to control the behaviour of the receive reference presented on the RSYNC. If RSYNC_ALOSB is a logic 0, analog loss of signal is used. If RSYNC_ALOSB is a logic 1, digital loss of signal is used. When COMET is in a loss of signal state, the RSYNC output is derived from XCLK. When PROPRIETARY AND CONFIDENTIAL 99 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 COMET is not in a loss of signal state, the RSYNC output is derived from the recovered receiver clock. 01 :2 IBCD_IDLE: ug us t, 20 07 When the IBCD_IDLE bit is set to logic 1 gaps the data to the inband code detector (IBCD) block during the framing bit. This allows the IBCD to be used to detect an idle code that is inserted only in the payload of the receive DS1 PCM stream. The IBCD must still be programmed to detect the desired pattern, and otherwise operates unchanged. The IBCD_IDLE bit is only valid in T1 mode. 2A TRKEN: o on Th ur sd ay ,0 The TRKEN bit enables receive trunk conditioning upon an out-of-frame condition. If TRKEN is logic 1, the contents of the RX-ELST Idle Code register are inserted into all time slots (including TS0 and TS16) of BRPCM if the framer is out-of-basic frame (i.e. the OOF status bit is logic 1). The TRKEN bit only has effect if RXELSTBYP bit is logic 0. If TRKEN is a logic 0, receive trunk conditioning can still be performed on a per-timeslot basis via the RPSC Data Trunk Conditioning and Signaling Trunk Conditioning registers. cir RXMTKC: ab do u ra s ha d of bn ha The RXMTKC bit allows global trunk conditioning to be applied to the received data and signaling streams, BRPCM and BRSIG. When RXMTKC is set to logic 1, the data on BRPCM for each channel is replaced with the data contained in the data trunk conditioning registers within RPSC; similarly, the signaling data on BRSIG for each channel is replaced with the data contained in the signaling trunk conditioning registers. When RXMTKC is set to logic 0, the data and signaling signals are modified on a per-channel basis in accordance with the control bits contained in the per-channel control registers within the RPSC. E1/T1B: Do wn l oa d ed by The E1/T1B bit selects the operating mode of COMET. If E1/T1B is logic 1, the 2.048 Mbit/s E1 mode is selected. If E1/T1B is logic 0, the 1.544 Mbit/s T1 mode is selected. PROPRIETARY AND CONFIDENTIAL 100 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X :2 Default 20 07 01 Function t, Type R XCLKA X Bit 3 R BTCLKA X Bit 2 R TCLKIA Bit 1 R BRCLKA Bit 0 R RCLKIA ug us Bit 4 2A Bit 6: Register 001H: Clock Monitor X sd ay ,0 X X cir o on Th ur When a monitored clock signal makes a low to high transition, the corresponding register bit is set high. The bit will remain high until this register is read, at which point all the bits in this register are cleared. A lack of transitions is indicated by the corresponding register bit reading low. This register should be read at periodic intervals to detect clock failures. ha BTCLKA: d of bn The BTCLK active (BTCLKA) bit detects low to high transitions on the BTCLK input. BTCLKA is set high on a rising edge of BTCLK, and is set low when this register is read. ha TCLKIA: ab do u ra s The TCLKI active (TCLKIA) bit detects low to high transitions on the TCLKI input. TCLKIA is set high on a rising edge of TCLKI, and is set low when this register is read. BRCLKA: oa d ed by The BRCLK active (BRCLKA) bit detects low to high transitions on the BRCLK input. BRCLKA is set high on a rising edge of BRCLK, and is set low when this register is read. Do wn l RCLKIA: The RCLKI active (RCLKA) bit detects low to high transitions on the RCLKI input. RCLKIA is set high on a rising edge of RCLKI, and is set low when this register is read. PROPRIETARY AND CONFIDENTIAL 101 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 XCLKA: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: The XCLK active (XCLKA) bit detects for low to high transitions on the XCLK input. XCLKA is set high on a rising edge of XCLK, and is set low when this register is read. PROPRIETARY AND CONFIDENTIAL 102 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W RJATBYP 1 Bit 6 R/W UNF 0 Bit 5 R/W RXELSTBYP 0 Bit 4 R/W RSYNC_MEM 0 Bit 3 R/W RSYNCSEL 0 Bit 2 R/W WORDERR Bit 1 R/W CNTNFAS Bit 0 R/W CCOFA ug us t, 20 07 01 :2 Bit 2A 6: Register 002H: Receive Options 0 sd ay ,0 0 0 Th ur This register allows software to configure the receive functions of each framer. on RJATBYP: d of bn ha cir o The RJATBYP bit disables jitter attenuation in the receive direction. When receive jitter attenuation is not being used, setting RJATBYP to logic 1 will reduce the latency through the receiver section by typically 40 bits. When RJATBYP is set to logic 0, the RSYNC output and the BRCLK output (if BRCLK is configured to be an output by setting the CMODE bit of the Receive Backplane Configuration register to logic 0), are jitter attenuated. When the RJAT is bypassed, RSYNC and BRCLK are not jitter attenuated. ha UNF: ed by ab do u ra s The UNF bit allows the framer to operate with unframed DS-1 or E1 data. When UNF is set to logic 1, the framer is disabled (both the T1-FRMR and E1-FRMR are held reset) and the recovered data passes through the receiver section of the framer without frame or channel alignment. While UNF is set to logic 1, the Alarm Integrator continues to operate and detects and integrates AIS alarm. When UNF is set to logic 0, the framer operates normally, searching for frame alignment on the incoming data. oa d When UNF is a logic 1, the BRFP pin (if configured as an output) is held low. Do wn l RXELSTBYP: The RXELSTBYP bit allows the Receive Elastic Store (RX-ELST) to be bypassed, eliminating the one frame delay incurred through the RX-ELST. PROPRIETARY AND CONFIDENTIAL 103 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 When set to logic 1, the received data and clock inputs to RX-ELST are internally routed directly to the RX-ELST output. 07 01 :2 If RXELSTBYP is logic 1, the CMODE bit of the Receive Backplane Configuration register must be logic 0 and the FPMODE bit of the Receive Backplane Frame Pulse Configuration register must be logic 0. 20 RSYNC_MEM: ,0 2A ug us t, The RSYNC_MEM bit controls the RSYNC output under a loss of signal condition (as determined by the RSYNC_ALOSB register bit). When RSYNC_MEM is a logic 1, the RSYNC output is held high during a loss of signal condition. When RSYNC_MEM is a logic 0, the RSYNC output is derived from XCLK during a loss of signal condition. ay RSYNCSEL: on Th ur sd The RSYNCSEL bit selects the frequency of the receive reference presented on the RSYNC output. If RSYNCSEL is a logic 1, RSYNC will be an 8 kHz clock. If RSYNCSEL is a logic 0, RSYNC will be an 1.544 MHz (T1) or 2.048 MHz (E1) clock. o WORDERR: of bn ha cir In E1 mode, the WORDERR bit determines how frame alignment signal (FAS) errors are reported. When WORDERR is logic 1, one or more errors in the seven bit FAS word results in a single framing error count. When WORDERR is logic 0, each error in a FAS word results in a single framing error count. d CNTNFAS: ab do u ra s ha In E1 mode, when the CNTNFAS bit is a logic 1, a zero in bit 2 of time slot 0 of non-frame alignment signal (NFAS) frames results in an increment of the framing error count. If WORDERR is also a logic 1, the word is defined as the eight bits consisting of the seven-bit FAS pattern and bit 2 of time slot 0 of the next NFAS frame. When the CNTNFAS bit is a logic 0, only errors in the FAS affect the framing error count. by CCOFA Do wn l oa d ed The CCOFA bit determines whether the PMON counts Change-Of-Frame Alignment (COFA) events or out-of-frame (OOF ) events. When CCOFA is set to logic 1, COFA events are counted by PMON. When CCOFA is set to logic 0, OOF events are counted by PMON. The CCOFA bit is only valid in T1 mode. PROPRIETARY AND CONFIDENTIAL 104 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W AUTOYELLOW 0 Bit 6 R/W AUTORED 0 Bit 5 R/W AUTOOOF 0 Bit 4 R/W AUTOAIS 0 Bit 3 R/W RUNI 0 Bit 2 R/W BPV Bit 1 R/W RDATINV Bit 0 R/W RFALL ug us t, 20 07 01 :2 Bit 2A 6: Register 003H: Receive Line Interface Configuration 0 sd ay ,0 0 Th ur AUTOYELLOW: 0 bn ha cir o on In T1 mode, when the AUTOYELLOW bit is set to logic 1, whenever the alarm integrator declares a Red alarm in the receive direction, Yellow alarm will be transmitted to the far end. When AUTOYELLOW is set to logic 0, Yellow alarm will only be transmitted when the XYEL bit is set in the T1-XBAS Alarm Transmit Register. Note that the Red alarm is not deasserted on detection of AIS. ab do u ra s ha d of In E1 mode, when the AUTOYELLOW bit is set to logic 1, The RAI bit in the transmit stream is set to a logic 1 for the duration of a loss of frame alignment or AIS. The G706ANNBRAI bit of the Transmit Framing and Bypass Options register optionally also allows for the transmission of RAI when CRC-to-nonCRC interworking has been established. When AUTOYELLOW is set to logic 0, RAI will only be transmitted when the RAI bit is set in the E1-TRAN Transmit Alarm/Diagnostic Control register. AUTORED: Do wn l oa d ed by The AUTORED bit allows global trunk conditioning to be applied to the receive data and signaling streams, BRPCM and BRSIG, immediately upon declaration of Red carrier failure alarm. When AUTORED is set to logic 1, the data on BRPCM for each channel is replaced with the data contained in the Data Trunk Conditioning registers within RPSC and the data on BRSIG for each channel is replaced with the data contained in the Signaling Trunk Conditioning registers within the RPSC while Red CFA is declared. When AUTORED is set to logic 0, the receive data is not automatically conditioned when Red CFA is declared. PROPRIETARY AND CONFIDENTIAL 105 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 AUTOOOF: 2A ug us t, 20 07 01 :2 6: The AUTOOOF bit allows global trunk conditioning to be applied to the receive data stream, BRPCM, immediately upon declaration of out of frame (OOF). When AUTOOOF is set to logic 1, while OOF is declared, the data on BRPCM for each channel is replaced with the data contained in the data trunk conditioning registers within RPSC. When AUTOOOF is set to logic 0, the ingress data is not automatically conditioned by RPSC when OOF is declared. However, if the RX-ELST is not bypassed, the RX-ELST trouble code will still be inserted in channel data while OOF is declared if the TRKEN register bit is logic 1. RPSC data and signaling trunk conditioning overwrites the RX-ELST trouble code. ,0 AUTOAIS: ur sd ay If the AUTOAIS bit is logic 1, AIS is inserted in the receive path and the signaling is frozen for the duration of a loss of signal condition. If AUTOAIS is logic 0, AIS may be inserted manually via the RAIS register bit. Th RUNI: cir o on The RUNI bit selects the source of receive data. If RUNI is a logic 1, the receive data stream and clock are expected to be presented on the RDAT and RCLKI inputs, respectively. of bn ha If RUNI is a logic 0, the receive data and clock will be recovered from the analog RXTIP and RXRING inputs. These inputs will typically be connected to a signal transformer and may exhibit the attenuation and dispersion characteristics of short or long haul lines. ha d BPV: Do wn l oa d ed by ab do u ra s In T1 mode, the BPV bit enables only bipolar violations to indicate line code violations and be accumulated in the PMON LCV Count Registers. When BPV is set to logic 1, BPVs (which are not part of a valid B8ZS signature if B8ZS line coding is used) generate an LCV indication and increment the PMON LCV counter. When BPV is set to logic 0, both BPVs (which are not part of a valid B8ZS signature if B8ZS line coding is used) and excessive zeros (EXZ) generate an LCV indication and increment the PMON LCV counter. Excessive zeros is a sequence of zeros greater than fifteen bits long for an AMI-coded signal and greater than seven bits long for a B8ZS-coded signal. In E1 mode, the BPV bit enables only bipolar violations to indicate line code violations and be accumulated in the PMON LCV Count Registers. (The O162 bit in the CDRC Configuration register provides two E1 LCV definitions.) When BPV is set to logic 1, BPVs (which are not part of a valid HDB3 PROPRIETARY AND CONFIDENTIAL 106 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 signature if HDB3 line coding is used) generate an LCV indication and increment the PMON LCV counter. When BPV is set to logic 0, both BPVs (which are not part of a valid HDB3 signature if HDB3 line coding is used) and excessive zeros (EXZ) generate an LCV indication and increment the PMON LCV counter. Excessive zeros is a sequence of zeros greater than four bits long. 20 RDATINV: 2A ug us t, When RDATINV is set to logic 1, the receive digital interface assumes the RDAT input is active low. When RDATINV is set to logic 0, the interface assumes the RDAT input is active high. ,0 This bit only has effect if the RUNI bit is logic 1. ay RFALL: Th ur sd When RFALL is set to logic 1, the RDAT signal is sampled by the falling RCLKI edge. When RFALL is set to logic 0, the RDAT signal is sampled by the rising RCLKI edge. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on This bit only has effect if the RUNI bit is logic 1. PROPRIETARY AND CONFIDENTIAL 107 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W TJATBYP 0 Bit 6 R/W TAISEN 0 Bit 5 R/W TAUXP 0 Bit 4 R/W TDATINV 0 Bit 3 R/W TUNI 0 Unused TRISE Unused sd Bit 0 07 20 t, us 0 ,0 R/W X ay Bit 1 ug 2A Bit 2 :2 Type 01 Bit 6: Register 004H: Transmit Line Interface Configuration X on Th ur This register enables the transmit interface to generate the required digital output waveform format. TJATBYP: bn ha cir o The TJATBYP bit enables the transmit jitter attenuator's FIFO to be removed from the transmit data path. When transmit jitter attenuation is not being used, setting TJATBYP to logic 1 will reduce the latency through the transmitter section by typically 40 bits. of TAISEN: by ab do u ra s ha d The TAISEN bit enables the interface to generate an unframed all-ones AIS alarm on the TXTIP, TXRING and TDAT pins. When TAISEN is set to logic 1 and TUNI is set to logic 0, the bipolar TXTIP and TXRING outputs are forced to pulse alternately, creating an all-ones signal; when TAISEN and TUNI are both set to logic 1, the unipolar TDAT output is forced to all-ones. The transition to transmitting AIS on the TXTIP and TXRING outputs is done in such a way as to not introduce any bipolar violations. oa d ed The TAISEN bit only takes effect when the AISE bit of the XLPG Control/Status register is logic 1. wn l The diagnostic loopback point is upstream of this AIS insertion point. Do TAUXP: The TAUXP bit enables the interface to generate an unframed alternating zeros and ones (i.e. 010101...) auxiliary pattern (AUXP) on the TXTIP, PROPRIETARY AND CONFIDENTIAL 108 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 TXRING and TDAT pins. When TAUXP is set to logic 1 and TUNI is set to logic 0, the bipolar TXTIP and TXRING outputs are forced to pulse alternately every other cycle; when TAUXP and TUNI are both set to logic 1, the unipolar TDAT output is forced to toggle every cycle. The transition to transmitting AUXP on the TXTIP and TXRING outputs is done in such a way as to not introduce any bipolar violations. t, 20 The diagnostic loopback point is upstream of this AUXP insertion point. us TDATINV: ,0 2A ug The TDATINV bit enables the digital transmit interface to logically invert the TDAT signal. When TDATINV is set to logic 1, the TDAT output is active low. When TDATINV is set to logic 0, the TDAT output is active high. sd ay TDATINV only has effect when TUNI is a logic 1. ur TUNI: Th The TUNI bit determines which interface presents the transmit data. of bn ha cir o on If TUNI is a logic 1, the transmit data is presented as TTL compatible unipolar data on the TDAT output with an associated clock on the TCLKO output and frame alignment pulse on the TFP output. The transmit line interface is held reset; therefore, the TXTIP and TXRING outputs are high-impedance. If TUNI is a logic 0, the transmit data is presented on the TXTIP and TXRING as pulses suitable for driving a transformer directly and the TDAT, TFP and TCLKO outputs are held low. d TRISE: Do wn l oa d ed by ab do u ra s ha When TRISE is set to logic 1, the interface is enabled to update the TDAT and TFP output pins on the rising edge of TCLKO. When TRISE is set to logic 0, the interface is enabled to update the outputs on the falling edge of TCLKO. PROPRIETARY AND CONFIDENTIAL 109 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W PATHCRC 0 Bit 6 R/W G706ANNBRAI 0 Bit 5 R/W SIGAEN 0 Bit 4 R/W OOCMFE0 0 Bit 3 R/W FDIS 0 Bit 2 R/W FBITBYP Bit 1 R/W CRCBYP Bit 0 R/W FDLBYP :2 Type 2A ug us t, 20 07 01 Bit 6: Register 005H: Transmit Framing and Bypass Options 0 sd ay ,0 0 0 on Th ur This register allows software to configure the bypass and framing options of the transmitter, the use of the Signaling Alignment block, and controls the global transmit framing disable. cir o PATHCRC: ha This bit only has effect in E1 mode. ab do u ra s ha d of bn When in E1 mode, the PATHCRC bit allows upstream block errors to be preserved in the transmit CRC bits. If PATHCRC is a logic 1, the CRC-4 bits are modified to reflect any bit values in BTPCM which have changed prior to transmission. When PATHCRC is set to logic 0, a new CRC-4 value overwrites the incoming CRC-4 word. For the PATHCRC bit to be effective, the FPTYP bit of the Transmit Backplane Frame Pulse Configuration register must be a logic 1; otherwise, the identification of the incoming CRC-4 bits would be impossible. The PATHCRC bit only takes effect if the GENCRC bit of the E1-TRAN Configuration register is a logic 1 and either the INDIS or FDIS bit in the same register are set to logic 1. by G706ANNBRAI: Do wn l oa d ed When in E1 mode, the G.706 Annex B RAI bit, G706ANNBRAI, selects between two modes of operation concerning the transmission of RAI when the COMET is out of CRC-4 multiframe. When G706ANNBRAI is logic 1, the behaviour of RAI follows Annex B of G.706, i.e., RAI is transmitted only when out of basic frame, not when CRC-4-to-non-CRC-4 interworking is declared, nor when the offline framer is out of frame. When G706ANNBRAI is logic 0, the behaviour of RAI follows ETSI standards, i.e., RAI is transmitted when out PROPRIETARY AND CONFIDENTIAL 110 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 of basic frame, when CRC-4-to-non-CRC-4 interworking is declared, and when the offline framer is out of frame. 01 :2 This bit only has effect in E1 mode. 07 SIGAEN: ay ,0 2A ug us t, 20 The SIGAEN bit enables the operation of the signaling aligner (SIGA) to ensure superframe alignment of signaling bits between the backplane and the transmit DS-1 stream. When set to logic 1, the SIGA is inserted into the signaling bit data path before the T1-XBAS. When the signaling aligner is used, the backplane frame alignment indication must also be changed to indicate superframe alignment for the transmit backplane. When SIGAEN is set to logic 0, the SIGA is removed from the circuit. It is recommended that SIGAEN be set to logic 1 in T1 mode. Th ur OOCMFE0: sd This bit has no effect in E1 mode. of bn ha cir o on When in E1 mode, the OOCMFE0 bit selects between two modes of operation concerning the transmission of E-bits when the COMET is out of CRC-4 multiframe. When OOCMFE0 is logic 0, the COMET transmits ones for the E-bits while out of CRC-4 multiframe. When OOCMFE0 is logic 1, the COMET transmits zeroes for the E-bits while out of CRC-4 multiframe. The option to transmit zeroes as E-bits while out of CRC-4 multiframe is provided to allow compliance with the CRC-4 to non-CRC-4 interworking procedure in Annex B of G.706. ha d This bit only has effect in E1 mode. ra s FDIS: by ab do u The FDIS bit allows the framing generation through the transmitter to be disabled and the transmit data to pass through the transmitter unchanged. When FDIS is set to logic 1, the transmitter is disabled from generating framing. When FDIS is set to logic 0, the transmitter is enabled to generate and insert the framing into the transmit data. ed FBITBYP: Do wn l oa d The FBITBYP bit allows the frame synchronization bit in the input data stream, BTPCM, to bypass the generation through the XBAS and be reinserted into the appropriate position in the digital output stream. When FBITBYP is set to logic 1, the input frame synchronization bit is re-inserted into the output data stream. When FBITBYP is set to logic 0, the XBAS is allowed to generate the output frame synchronization bits. PROPRIETARY AND CONFIDENTIAL 111 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 This bit must be set to logic 0 when not in T1 ESF mode. :2 6: CRCBYP: 20 07 01 In T1 mode, when the CRCBYP bit is a logic 1, the framing bit corresponding to the CRC-6 bit position in the input data stream, BTPCM, passes transparently to the transmit output data stream. When CRCBYP is set to logic 0, the XBAS is allowed to generate the output CRC-6 bits. us t, This bit must be set to logic 0 when not in T1 ESF mode. ug FDLBYP: sd ay ,0 2A In T1 mode, when the FDLBYP bit is a logic 1, the framing bit corresponding to the facility data link bit position in the input data stream, BTPCM, passes transparently to the transmit output data stream. When FDLBYP is set to logic 0, the XBAS is allowed to generate the output facility data link. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur This bit must be set to logic 0 when not in T1 ESF mode. PROPRIETARY AND CONFIDENTIAL 112 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X :2 Default 07 01 Function 20 Type R/W OCLKSEL1 0 Bit 4 R/W OCLKSEL0 0 Bit 3 R/W PLLREF1 0 Bit 2 R/W PLLREF0 TXELSTBYP us ay R/W X ,0 Unused Bit 0 ug 0 sd Bit 1 t, Bit 5 2A Bit 6: Register 006H: Transmit Timing Options 1 on Th ur This register allows software to configure the options of the transmit timing section. TXELSTBYP: bn ha cir o The TXELSTBYP bit allows the Transmit Elastic Store (TX-ELST) to be bypassed, eliminating the one frame delay incurred through the TX-ELST. When set to logic 1, the received data and clock inputs to TX-ELST are internally routed directly to the TX-ELST outputs. of OCLKSEL1, OCLKSEL0: - TJAT FIFO Output Clock Source ab do u Table 17 ra s ha d The OCLKSEL[1:0] bits select the source of the Transmit Jitter Attenuator FIFO output clock signal. OCLKSEL1 0 The TJAT FIFO output clock is driven with the internal jitter-attenuated 1.544 MHz or 2.048 MHz clock. 0 1 The TJAT FIFO output clock is driven with the TCLKI input clock. In this mode, PLLREF[1:0] must be programmed to `b11. ed by 0 Do wn l oa d OCLKSEL0 Source of FIFO Output Clock PROPRIETARY AND CONFIDENTIAL 113 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 The TJAT FIFO output clock is driven with the FIFO input clock. In this mode the jitter attenuation is disabled and the input clock must be jitter-free. In this mode, PLLREF[1:0] must be programmed to `b00. :2 X 20 07 01 1 50 OCLKSEL0 Source of FIFO Output Clock 6: OCLKSEL1 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 us t, PLLREF1, PLLREF0: ,0 - TJAT PLL Source PLLREF0 Source of PLL Reference 0 0 TJAT FIFO input clock (either the conditioned BTCLK or the receive recovered clock, as selected by LINELB, assuming the TX-ELST is bypassed) 0 1 conditioned BTCLK input (assuming the TX-ELST is bypassed) 1 0 Receive recovered clock 1 1 cir o on Th ur sd ay PLLREF1 ha Table 18 2A ug The PLLREF[1:0] bits select the source of the Transmit Jitter Attenuator phase locked loop reference signal as follows: bn TCLKI input ra s ha d of If the BTCLK is configured as an output (CMODE bit of the Transmit Backplane Configuration register is a logic 0), only the recovered clock or the TCLKI input should be selected, or else the timing becomes self-referential and unpredictable. ab do u The following table illustrates the required bit settings for these various clock sources to affect the transmitted data: - Transmit Timing Options Summary Input Transmit Data Bit Settings Effect on Output Transmit Data ed by Table 19 OCLKSEL1=0 Jitter attenuated. TCLKO is a smooth 1.544 MHz or Transmit Backplane Configuration OCLKSEL0=0 2.048 MHz. register CMODE =1. PLLREF1=0 TCLKO referenced to BTCLK input. TX-ELST bypassed. Do wn l oa d Synchronous to BTCLK input. PROPRIETARY AND CONFIDENTIAL PLLREF0=X LINELB=0 TXELSTBYP=1 114 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Bit Settings Effect on Output Transmit Data Synchronous to BTCLK output. OCLKSEL1=0 Jitter attenuated looptiming. TCLKO is a smooth Transmit Backplane Configuration OCLKSEL0=0 1.544 MHz or 2.048 MHz. register CMODE =0. PLLREF1=1 Loop timed to the receive recovered clock. TX-ELST 6: :2 01 bypassed. 07 PLLREF0=0 50 Input Transmit Data 20 LINELB=0 us t, TXELSTBYP=1 OCLKSEL1=0 Jitter attenuated looptiming. TCLKO is a smooth Transmit Backplane Configuration OCLKSEL0=0 1.544 MHz or 2.048 MHz. register CMODE =1. PLLREF1=1 Loop timed to the receive recovered clock. TX-ELST 2A ug Synchronous to BTCLK input. allows BTCLK to be plesiochronous. ,0 PLLREF0=0 Transmit Backplane Configuration OCLKSEL0=0 register CMODE =0. PLLREF1=1 sd OCLKSEL1=0 Jitter attenuated. TCLKO is a smooth 1.544 MHz or 2.048 MHz. TCLKO and BTCLK referenced to TCLKI input. TX-ELST bypassed. on Th Synchronous to BTCLK output. ur TXELSTBYP=0 ay LINELB=0 o PLLREF0=1 cir LINELB=0 ha TXELSTBYP=1 OCLKSEL1=0 bn Synchronous to BTCLK input. OCLKSEL0=0 register CMODE =1. PLLREF1=1 ab do u ra s ha d of Transmit Backplane Configuration Jitter attenuated. TCLKO is a smooth 1.544 MHz or 2.048 MHz. TCLKO referenced to TCLKI input. TXELST allows BTCLK to be plesiochronous. PLLREF0=1 LINELB=0 TXELSTBYP=0 Synchronous to BTCLK input. OCLKSEL1=1 No jitter attenuation. TCLKO is equivalent to BTCLK. Transmit Backplane Configuration OCLKSEL0=X TX-ELST bypassed. PLLREF1=1 PLLREF0=1 LINELB=0 TXELSTBYP=1 Do wn l oa d ed by register CMODE =1. PROPRIETARY AND CONFIDENTIAL 115 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Bit Settings Effect on Output Transmit Data Synchronous to BTCLK output. OCLKSEL1=0 No jitter attenuation. TCLKO is equal to TCLKI (useful Transmit Backplane Configuration OCLKSEL0=1 for higher rate MUX applications). The BTCLK output 6: :2 referenced to TCLKI. TX-ELST bypassed. 01 register CMODE =0. PLLREF1=1 07 PLLREF0=1 20 LINELB=0 us OCLKSEL0=1 for higher rate MUX applications). TX-ELST allows ug Transmit Backplane Configuration register CMODE =1. No jitter attenuation. TCLKO is equal to TCLKI (useful BTCLK to be plesiochronous. 2A OCLKSEL1=0 t, TXELSTBYP=1 Synchronous to BTCLK input. PLLREF1=1 ,0 PLLREF0=1 OCLKSEL0=0 sd OCLKSEL1=0 Line loopback with jitter attenuation. Th Transmit data ignored. Receive data ur TXELSTBYP=0 ay LINELB=0 is looped back. 50 Input Transmit Data on PLLREF1=X o PLLREF0=0 cir LINELB=1 bn ha TXELSTBYP=X Do wn l oa d ed by ab do u ra s ha d of Upon reset of the COMET, these bits are cleared to zero, selecting jitter attenuation with TCLKO referenced to the backplane transmit clock, BTCLK. Figure 12 illustrates the various bit setting options, with the reset condition highlighted. When TUNI is logic 0, PLLREF[1:0] must be configured such that the internal 24x clock references the Transmit line clock. PROPRIETARY AND CONFIDENTIAL 116 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 :2 0 TXELSTBY P 1 FIFO output data clock LINELB Internal 24x clock 0 1 00 Receive recovered clock sd 10 ay PLLREF[1:0] 11 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur TCLKI PROPRIETARY AND CONFIDENTIAL 117 TJAT PLL ,0 01 2A ug us t, 1 OCLKSEL1 TJAT FIFO FIFO input data clock 0 01 Optional freq. division and gapping 50 6: Transmit line clock, TCLKO (becomes BTCLK output w hen CMODE=0) TX ELST 07 BTCLK (input) - Transmit Timing Options 20 Figure 12 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 OCLKSEL0 1 "Jitter-free" line rate clock (1.544MHz or 2.048MHz) 0 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R PMON 0 Bit 6 R PRGD 0 Bit 5 R FRMR 0 Bit 4 R SIGX 0 Bit 3 R APRM 0 Bit 2 R TJAT Bit 1 R RJAT 2A Bit 0 R CDRC ug us t, 20 07 01 :2 Type 0 ay ,0 0 sd Bit 6: Register 007H: Interrupt Source #1 0 on Th ur This register allows software to determine the block which produced the interrupt on the INTB output pin. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o Reading this register does not remove the interrupt indication; the corresponding block's interrupt status register must be read to remove the interrupt indication. PROPRIETARY AND CONFIDENTIAL 118 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R RX-ELST 0 Bit 6 R RDLC #3 0 Bit 5 R RDLC #2 0 Bit 4 R RDLC #1 0 Bit 3 R TX-ELST 0 Bit 2 R TDPR #3 Bit 1 R TDPR #2 2A Bit 0 R TDPR #1 ug us t, 20 07 01 :2 Type 0 ay ,0 0 sd Bit 6: Register 008H: Interrupt Source #2 0 on Th ur This register allows software to determine the block that produced the interrupt on the INTB output pin. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o Reading this register does not remove the interrupt indication; the corresponding block's interrupt status register must be read to remove the interrupt indication. PROPRIETARY AND CONFIDENTIAL 119 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R IBCD 0 Bit 6 R PDVD 0 Bit 5 R RBOC 0 Bit 4 R XPDE 0 Bit 3 R ALMI 0 Bit 2 R TRAN Bit 1 R RLPS 2A Bit 0 R BTIF ug us t, 20 07 01 :2 Type 0 ay ,0 0 sd Bit 6: Register 009H: Interrupt Source #3 0 on Th ur This register allows software to determine the block that produced the interrupt on the INTB output pin. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o Reading this register does not remove the interrupt indication; the corresponding block's interrupt status register must be read to remove the interrupt indication. PROPRIETARY AND CONFIDENTIAL 120 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R ID[5] 1 Bit 5 R/W PAYLB 0 Bit 4 R/W LINELB 0 Bit 3 R/W RAIS 0 Bit 2 R/W DDLB Bit 1 R/W TXMFP Bit 0 R/W TXLOS ug us t, 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 00AH: Master Diagnostics 0 sd ay ,0 0 Th ur ID[5]: 0 cir o on The ID[5] bit was added for COMET Rev G. In prior revisions, this bit was unused and defaulted to X. Please see the Register 00DH: Revision/Chip ID/Global PMON Update description for how to distinguish between COMET Rev F and G in software. ha PAYLB: wn l oa d ed by ab do u ra s ha d of bn The PAYLB bit selects the payload loopback mode, where the received data output from the RX-ELST is internally connected to the transmit data input of the transmitter. The data read out of RX-ELST is timed to the transmitter clock, and the transmit frame alignment is used to synchronize the output frame alignment of RX-ELST. The transmit frame alignment is either arbitrary (when the TX-ELST is used) or is specified by the BTFP input (when the TXELST is bypassed). During payload loopback, the data on BRPCM is only valid when the COMET is configured as a BRCLK master, BRFP master and the RX-ELST is bypassed. When the RX-ELST is not bypassed, the BRPCM output is forced to all-ones. When PAYLB is set to logic 1, the payload loopback mode is enabled. When PAYLB is set to logic 0, the loopback mode is disabled. In T1 mode, if the TDPR #1 is configured to send performance reports from the T1-APRM, this bit requires two updating cycles before being included in the performance report. Only one of PAYLB, LINELB, and DDLB can be enabled at any one time. Do LINELB: The LINELB bit selects the line loopback mode, where the recovered data are internally directed to the digital inputs of the transmit jitter attenuator. In PROPRIETARY AND CONFIDENTIAL 121 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 ug us t, 20 07 01 :2 6: 50 analog mode (RUNI is logic 0), the data sent to the TJAT is the recovered data from the output of the CDRC block. In digital mode (RUNI is logic 1), the data sent to the TJAT is a sampled version of the RDAT digital input. When LINELB is set to logic 1, the line loopback mode is enabled. When LINELB is set to logic 0, the line loopback mode is disabled. Note that when line loopback is enabled, to correctly attenuate the jitter on the receive clock, the contents of the TJAT Reference Clock Divisor and Output Clock Divisor registers should be programmed to 2FH in T1 or FFH in E1 and the Transmit Timing Options register should be cleared to all zeros. Only one of PAYLB, LINELB, and DDLB can be enabled at any one time. 2A RAIS: ur sd ay ,0 When a logic 1, the RAIS bit forces all ones into the BRPCM data stream. The BRSIG data stream will freeze at the current valid signaling. This capability is provided to indicate the unavailability of the line when line loopback is active. Th DDLB: ra s TXMFP: ha d of bn ha cir o on The DDLB bit selects the diagnostic digital loopback mode, where the COMET is configured to internally direct the output of the TJAT to the inputs of the receiver section. In analog mode (RUNI is logic 0), the dual-rail RZ outputs of the TJAT are directed to the dual-rail inputs of the CDRC. In digital mode (RUNI is logic 1), the single-rail NRZ outputs of the TJAT are directed to the inputs of the RJAT. When DDLB is set to logic 1, the diagnostic digital loopback mode is enabled. When DDLB is set to logic 0, the diagnostic digital loopback mode is disabled. When configured for diagnostic digital loopback, the TUNI and RUNI bits must be set to the same value. Only one of PAYLB, LINELB, and DDLB can be enabled at any one time. ed by ab do u In T1 mode, the TXMFP bit introduces a mimic framing pattern in the digital output of the basic transmitter by forcing a copy of the current framing bit into bit location 1 of the frame, thereby creating a mimic pattern in the bit position immediately following the correct framing bit. When TXMFP is set to logic 1, the mimic framing pattern is generated. When TXMFP is set to logic 0, no mimic pattern is generated. Do wn l oa d TXLOS: The TXLOS bit provides a method of suppressing the output of the transmitter in T1 digital mode. When TXLOS is set to logic 1, the E1/T1B bit in the Global Configuration register is a logic 0 and the TUNI bit in the Transmit Line Interface Configuration register is a logic 1, the transmit output, TDAT is forced to all-zeros. In both E1 and T1 analog mode (TUNI is logic 0), the PROPRIETARY AND CONFIDENTIAL 122 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 TXTIP and TXRING outputs can be forced to all-zeros by programming the XLPG Line Driver Configuration register. PROPRIETARY AND CONFIDENTIAL 123 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 X X Bit 5 W PMCATST X Bit 4 W PMCTST X Bit 3 W DBCTRL 0 Bit 2 R/W IOTST Bit 1 W HIZDATA Bit 0 R/W HIZIO 07 IDDQEN 20 W 2A Bit 6 :2 Unused 01 Default t, Bit 7 Function us Type ug Bit 6: Register 00BH: Master Test 0 sd ay ,0 0 0 o on Th ur This register is used to select COMET test features. All bits, except for PMCTST, PMCATST and IDDQEN are reset to zero by a hardware reset of the COMET; a software reset of the COMET does not affect the state of the bits in this register. Refer to the Test Features Description section for more information. cir IDDQEN: d of bn ha The IDDQEN bit is used to configure the COMET for IDDQ tests. IDDQEN is cleared when CSB is high and RSTB is low or when IDDQEN is written as logic 0. When the IDDQEN bit is set to logic 1, the HIGHZ bit in the XLPG Line Driver Configuration register must also be set to logic 1. ha PMCATST: ab do u ra s The PMCATST bit is used to configure the analog portion of the COMET for PMC's manufacturing tests. PMCATST is cleared when CSB is high and RSTB is low or when PMCATST is written as logic 0. PMCTST: Do wn l oa d ed by The PMCTST bit is used to configure the COMET for PMC's manufacturing tests. When PMCTST is set to logic 1, the COMET microprocessor port becomes the test access port used to run the PMC manufacturing test vectors. The PMCTST bit is logically "ORed" with the IOTST bit, and is cleared by setting CSB high. DBCTRL: The DBCTRL bit is used to pass control of the data bus drivers to the CSB pin. When the DBCTRL bit is set to logic 1, the CSB pin controls the output PROPRIETARY AND CONFIDENTIAL 124 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 enable for the data bus. While the DBCTRL bit is set, holding the CSB pin high causes the COMET to drive the data bus and holding the CSB pin low tristates the data bus. The DBCTRL bit overrides the HIZDATA bit. The DBCTRL bit only has effect when the IOTST or PMCTST bit is set to logic 1. The DBCTRL bit is used to measure the drive capability of the data bus driver pads. 20 IOTST: ay ,0 2A ug us t, The IOTST bit is used to allow normal microprocessor access to the test registers and control the test mode in each block in the COMET for board level testing. When IOTST is a logic 1, all blocks are held in test mode and the microprocessor may write to a block's test mode 0 registers to manipulate the outputs of the block and consequently the device outputs (refer to the "Test Mode 0 Details" in the "Test Features" section). sd HIZIO, HIZDATA: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur The HIZIO and HIZDATA bits control the tri-state modes of the COMET . While the HIZIO bit is a logic 1, all output pins of the COMET except the data bus are held in a high-impedance state. The microprocessor interface is still active. While the HIZDATA bit is a logic 1, the data bus is also held in a highimpedance state which inhibits microprocessor read cycles. PROPRIETARY AND CONFIDENTIAL 125 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X :2 Default 07 01 Function 20 Type R/W Reserved 0 Bit 4 R/W Reserved 0 Bit 3 Unused X Bit 2 Unused ug us t, Bit 5 2A Bit 6: Register 00CH: Analog Diagnostics X R/W Reserved ,0 Bit 0 0 ay Reserved sd R/W 0 ur Bit 1 Th Reserved: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on These bits must be a logic 0 for correct operation. PROPRIETARY AND CONFIDENTIAL 126 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R TYPE[2] 0 Bit 6 R TYPE[1] 0 Bit 5 R TYPE[0] 1 Bit 4 R ID[4] 0 Bit 3 R ID[3] 0 Bit 2 R ID[2] Bit 1 R ID[1] 2A Bit 0 R ID[0] ug us t, 20 07 01 :2 Type 1 ay ,0 0 sd Bit 6: Register 00DH: Revision/Chip ID/Global PMON Update 1 on Th ur The version identification bits, ID[4:0], are set to a fixed value representing the version number of the COMET. For COMET Rev G, ID[5] was added to the Master Diagnostics register (address 00AH). ha cir o In order to uniquely identify Rev G in software, the following routine can be executed: of bn i. Read Register 00DH: Revision/Chip ID/Global PMON Update. Revision F or Revision G will contain "00100101". ra s ha d ii. Read Register 00AH: Master Diagnostics. In Revision F, bit 6 will read logic 0, as this is the value charged on the bus-holder due to the last read. In Revision G, bit 6 will read logic 1, as this is the value driven by the new ID[5] bit. by ab do u NOTE: For this two step sequence to work, step (ii) must follow immediately after step (i) without any intervening microprocessor accesses. Any intervening accesses could change the value charged onto the bit 6 bus-holder, invalidating step (ii). oa d ed Writing any value to this register causes all performance monitor counters to be updated simultaneously. Do wn l The chip identification bits, TYPE[2:0], are set to "001" representing the COMET. PROPRIETARY AND CONFIDENTIAL 127 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 R/W ug us t, 20 07 01 :2 Function X ,0 X ay Type RESET sd Bit 6: Register 00EH: Reset Th ur RESET: 0 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The RESET bit implements a software reset. If the RESET bit is a logic 1, the COMET is held in reset. This bit is not self-clearing; therefore, a logic 0 must be written to bring the COMET out of reset. Holding the COMET in a reset state effectively puts it into a low-power, stand-by mode. A hardware reset clears the RESET bit, thus deasserting the software reset. PROPRIETARY AND CONFIDENTIAL 128 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W HDLC3_DIS 0 Bit 6 R/W HDLC2_DIS 0 Bit 5 R/W HDLC1_DIS 0 Bit 4 R/W Nx56k_GEN 0 Bit 3 R/W Nx56k_DET 0 Bit 2 R/W RXPATGEN Bit 1 R/W UNF_GEN Bit 0 R/W UNF_DET ug us t, 20 07 01 :2 Bit 2A 6: Register 00FH: PRGD Positioning/Control and HDLC Control 0 sd ay ,0 0 0 on Th ur This register modifies the way in which the PRGD is used by the TPSC and RPSC. More information on using PRGD is available in the Operation section. HDLC3_DIS: bn ha cir o The HDLC3_DIS bit, when set to logic 1, is used to disable the clock to the TDPR #3 and RDLC #3, putting them into a low power, stand-by mode. When the HDLC3_DIS bit is set to logic 0, the clock to the TDPR #3 and RDLC #3 is enabled. of HDLC2_DIS: ab do u ra s ha d The HDLC2_DIS bit, when set to logic 1, is used to disable the clock to the TDPR #2 and RDLC #2, putting them into a low power, stand-by mode. When the HDLC2_DIS bit is set to logic 0, the clock to the TDPR #2 and RDLC #2 is enabled. HDLC1_DIS: oa d ed by The HDLC1_DIS bit, when set to logic 1, is used to disable the clock to the TDPR #1 and RDLC #1, putting them into a low power, stand-by mode. When the HDLC1_DIS bit is set to logic 0, the clock to the TDPR #1 and RDLC #1 is enabled. Do wn l Nx56k_GEN: The Nx56k_GEN bit is active when the RPSC or TPSC is used to insert PRBS into selected DS0 channels of the transmit or receive stream. When the Nx56kbps generation bit is set to logic 1, the pattern is only inserted in the first 7 bits of the selected DS0 channels, and gapped on the eighth bit. This is PROPRIETARY AND CONFIDENTIAL 129 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 particularly useful when using the jammed-bit-8 zero code suppression in the transmit direction, for instance when sending a Nx56kbps fractional T1/E1 loopback sequence. This bit has no effect when UNF_GEN is set to logic 1. 01 Nx56k_DET: 2A ug us t, 20 07 The Nx56k_DET bit is active when the RPSC or TPSC is used to detect PRBS in selected DS0 channels of the transmit or receive stream. When the Nx56kbps detection bit is set to logic 1, the pattern generator only looks at the first 7 bits of the selected DS0 channels, and gaps out the eighth bit. This is particularly useful when searching for fractional T1 loopback codes in an Nx56kbps fractional T1 signal. This bit has no effect when UNF_DET is set to logic 1. ,0 RXPATGEN: d of bn ha cir o on Th ur sd ay The Receive Pattern Generate (RXPATGEN) bit controls the location of the pattern generator/detector. When RXPATGEN is set to logic 1, the pattern generator is inserted in the receive path and the pattern detector is inserted in the transmit path. Timeslots from the receive line may be overwritten with generated patterns before appearing on the receive backplane interface, and timeslots from the transmit backplane interface may be checked for the generated pattern before appearing on the transmit line. When RXPATGEN is set to logic 0, the pattern detector is inserted in the receive path and the pattern generator is inserted in the transmit path. Timeslots from the transmit backplane interface may be overwritten with generated patterns before appearing on the transmit line, and timeslots from the receive line may be checked for the generated pattern before appearing on the receive backplane interface. ra s ha UNF_GEN wn l oa d ed by ab do u When the Unframed Pattern Generation bit (UNF_GEN) is set to logic 1, the PRGD will overwrite all 193 bits/256 bits in every frame in the direction specified by the RXPATGEN bit. If the generator is enabled in the transmit path, unless signaling and/or framing is disabled, the transmitter will still overwrite the signaling bit positions and/or the framing bit position. Similarly, if pattern generation is enabled in the receive direction, the pattern will overwrite the framing bit positions. The UNF_GEN bit overrides any pertimeslot pattern generation specified in the TPSC or RPSC. When RXPATGEN = 0, UNF_GEN also overrides idle code insertion and data inversion in the transmit direction, just like the TEST bit in the TPSC. Do UNF_DET When the Unframed Pattern Detection bit (UNF_DET) is set to logic 1, the PRGD will search for the pattern in all 193 bits/256 bits of the transmit or PROPRIETARY AND CONFIDENTIAL 130 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 receive stream, depending on the setting of RXPATGEN. The UNF_DET bit overrides any per-timeslot pattern detection specified in the TPSC or RPSC. PROPRIETARY AND CONFIDENTIAL 131 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W AMI 0 Bit 6 R/W LOS[1] 0 Bit 5 R/W LOS[0] 0 Bit 4 R/W Reserved 0 Bit 3 R/W Reserved 0 Bit 2 R/W ALGSEL Bit 1 R/W O162 Bit 0 R/W Reserved ug us t, 20 07 01 :2 Bit 2A 6: Register 010H: CDRC Configuration 0 sd ay ,0 0 0 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. o Reserved: cir These bits must be a logic 0 for correct operation. bn ha O162: d of If the AMI bit is logic 0 in E1 mode, the Recommendation O.162 compatibility select bit (O162) allows selection between two line code violation definitions: ab do u ra s ha If O162 is a logic 0, a line code violation is indicated if the serial stream does not match the verbatim HDB3 definition given in Recommendation G.703. A bipolar violation that is not part of an HDB3 signature or a bipolar violation in an HDB3 signature that is the same polarity as the last bipolar violation results in a line code violation indication. by If O162 is a logic 1, a line code violation is indicated if a bipolar violation is of the same polarity as the last bipolar violation, as per Recommendation O.162. oa d ed The O162 bit has no effect in T1 mode. Do wn l ALGSEL: The Algorithm Select (ALGSEL) bit specifies the algorithm used by the DPLL for clock and data recovery. The choice of algorithm determines the high frequency input jitter tolerance of the CDRC. When ALGSEL is set to logic 1, the CDRC jitter tolerance is increased to approach 0.5 UIpp for jitter PROPRIETARY AND CONFIDENTIAL 132 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 6: 50 frequencies above 20 kHz. When ALGSEL is set to logic 0, the jitter tolerance is increased for frequencies below 20 kHz (i.e. the tolerance is improved by 20% over that of ALGSEL=1 at these frequencies), but the tolerance approaches 0.4 UIpp at the higher frequencies. 07 AMI: 2A ug us t, 20 The alternate mark inversion (AMI) bit specifies the line coding of the incoming signal. A logic 1 selects AMI line coding by disabling HDB3 decoding if E1 mode and B8ZS in T1 mode. In E1 mode, a logic 0 selects HDB3 line decoding which entails substituting an HDB3 signature with four zeros. In T1 mode, a logic 0 selects B8ZS line decoding which entails substituting an B8ZS signature with eight zeros. ,0 LOS[1:0]: ur sd ay The loss of signal threshold is set by the operating mode and the state of the AMI, LOS[1] and LOS[0] bits: - Loss of Signal Thresholds AMI LOS[1] LOS[0] E1 0 0 0 T1 0 0 0 X 1 0 X X 0 X X 1 X X 1 o cir ha 15 15 1 31 0 63 1 175 bn 0 of d 10 ra s ha Threshold (PCM periods) on Mode Th Table 20 Do wn l oa d ed by ab do u When the number of consecutive zeros on the incoming PCM line exceeds the programmed threshold, the LOSV status bit is set. For example, if the threshold is set to 10, the 11th zero causes the LOSV bit to be set. The LOSV bit clears when a pulse occurs. PROPRIETARY AND CONFIDENTIAL 133 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W LCVE 0 Bit 6 R/W LOSE 0 Bit 5 R/W LCSDE 0 Bit 4 R/W ZNDE 0 Bit 3 Unused X Bit 2 Unused Bit 1 Unused Bit 0 Unused ug us t, 20 07 01 :2 Bit 2A 6: Register 011H: CDRC Interrupt Control X sd ay ,0 X X on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. d of bn ha cir o The bit positions LCVE, LOSE, LCSDE and ZNDE (bits 7 to 4) of this register are interrupt enables to select which of the status events (Line Code Violation , Loss Of Signal, HDB3 signature, B8ZS signature or N Zeros), either singly or in combination, are enabled to generate an interrupt on the microprocessor INTB pin when they are detected. A logic 1 bit in the corresponding bit position enables the detection of these signals to generate an interrupt; a logic 0 bit in the corresponding bit position disables that signal from generating an interrupt. Do wn l oa d ed by ab do u ra s ha When the COMET is reset, LCVE, LOSE, LCSDE and ZNDE are set to logic 0, disabling these events from generating an interrupt. PROPRIETARY AND CONFIDENTIAL 134 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R LCVI X Bit 6 R LOSI X Bit 5 R LCSDI X Bit 4 R ZNDI X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A R 01 07 20 t, us ug X ,0 X ay Bit 0 :2 Type LOSV sd Bit 6: Register 012H: CDRC Interrupt Status X on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. bn ha cir o The ZNDI, LCSDI, LOSI and LCVI (bits 4 to 7) of this register indicate which of the status events have occurred since the last time this register was read. A logic 1 in any of these bit positions indicates that the corresponding event was detected. of Bits ZNDI, LCSDI, LOSI and LCVI are cleared to logic 0 by reading this register. d LOSV: ra s ha The LOSV bit reflects the status of the LOS alarm. ab do u ZNDI: by The consecutive zeros detection interrupt (ZNDI) indicates that N consecutive spaces have occurred, where N is four for E1 and eight for T1. This bit can be used to detect an AMI coded signal. ed LCSDI: Do wn l oa d The line code signature detection interrupt (LCSDI) indicates that a valid line code signature has occurred. In T1 mode, the B8ZS signature is defined as 000+-0-+ if the previous impulse is positive, or 000-+0+- if it is negative. In E1 mode, a valid HDB3 signature is defined as a bipolar violation preceded by two zeros. This bit can be used to detect an HDB3 coded signal in E1 mode and B8ZS coded signal in T1. PROPRIETARY AND CONFIDENTIAL 135 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 LOSI: :2 6: The LOSI bit is set to a logic 1 when the LOSV bit changes state. 01 LCVI: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 The line code violation interrupt (LCVI) indicates a series of marks and spaces has occurred in contradiction to the defined line code (AMI, B8ZS or HDB3). PROPRIETARY AND CONFIDENTIAL 136 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W ALTLOSE 0 Bit 6 R ALTLOSI X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 01 07 20 t, us ug ,0 X ay R X ALTLOS sd Bit 0 :2 Bit 2A 6: Register 013H: Alternate Loss of Signal Status X on Th ur This register is only operational when the RUNI bit of the Receive Line Interface Configuration register is a logic 0. ha cir o The alternate loss of signal status provides a more stringent criteria for the deassertion of the alarm than the LOS indication in the CDRC Interrupt Status register. bn ALTLOSE: d of If the ALTLOSE bit is a logic 1, the INTB output is asserted low when the ALTLOS status bit changes state. ha ALTLOSI: ab do u ra s The ALTLOSI bit is set high when the ALTLOS status bit changes state. It is cleared when this register is read. ALTLOS: Do wn l oa d ed by The ALTLOS bit is asserted upon the absence of marks for the threshold of bit periods specified by the LOS[1:0] register bits. The ALTLOS bit is deasserted only after pulse density requirements have been met. In T1 mode, there must be N ones in each and every time window of 8(N+1) data bits (where N can equal 1 through 23). In E1 mode, ALTLOS is deasserted only after 255 bit periods during which no sequence of four zeros has been received. PROPRIETARY AND CONFIDENTIAL 137 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused 2A R OVRI Bit 0 R UNDI 01 07 20 t, us ug X X ,0 Bit 1 :2 Function ay Type sd Bit 6: Register 014H: RJAT Interrupt Status Th ur UNDI: X cir o on The UNDI bit is asserted when an attempt is made to read data from the receive FIFO when the FIFO is already empty. When UNDI is a logic 1, an underrun event has occurred. Reading this register will clear the UNDI bit to logic 0. ha OVRI: Do wn l oa d ed by ab do u ra s ha d of bn The OVRI bit is asserted when an attempt is made to write data into the receive FIFO when the FIFO is already full. When OVRI is a logic 1, an overrun event has occurred. Reading this register will clear the OVRI bit to logic 0. PROPRIETARY AND CONFIDENTIAL 138 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W N1[7] 0 Bit 6 R/W N1[6] 0 Bit 5 R/W N1[5] 1 Bit 4 R/W N1[4] 0 Bit 3 R/W N1[3] 1 Bit 2 R/W N1[2] Bit 1 R/W N1[1] Bit 0 R/W N1[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 015H: RJAT Divider N1 Control 1 sd ay ,0 1 1 cir o on Th ur This register contains an 8-bit binary number, N1, which is one less than the magnitude of the reference clock divisor. The reference divisor magnitude, (N1+1), is the ratio between the frequency of the recovered clock (or the transmit clock if a diagnostic loopback is enabled) and the frequency at the phase discriminator input. of bn ha Writing to this register will reset the PLL. If the FIFORST bit of the RJAT Configuration register is set high, a write to this register will reset both the PLL and FIFO. Do wn l oa d ed by ab do u ra s ha d The default value of N1 after a device reset is 47 = 2FH. PROPRIETARY AND CONFIDENTIAL 139 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W N2[7] 0 Bit 6 R/W N2[6] 0 Bit 5 R/W N2[5] 1 Bit 4 R/W N2[4] 0 Bit 3 R/W N2[3] 1 Bit 2 R/W N2[2] Bit 1 R/W N2[1] Bit 0 R/W N2[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 016H: RJAT Divider N2 Control 1 sd ay ,0 1 1 o on Th ur This register contains an 8-bit binary number, N2, which is one less than the magnitude of the output clock divisor. The output clock divisor magnitude, (N2+1), is the ratio between the frequency of the smooth output clock, BRCLK, and the frequency applied to the phase discriminator input. ha cir Writing to this register will reset the PLL. of bn Writing to this register will reset the PLL. If the FIFORST bit of the RJAT Configuration register is set high, a write to this register will reset both the PLL and FIFO. ha d The default value of N2 after a device reset is 47 = 2FH. ra s Recommendations ab do u In general, the relationship N1 = N2 must always be true in order for the PLL to operate correctly. oa d ed by In order to meet jitter transfer specifications for some modes, such as basic E1 operation, N1 and N2 must be large in order to reduce the PLL transfer cutoff frequency. In general, for E1 operation, N2 is set to FFH to meet ETSI jitter transfer specifications. Do wn l For T1 mode, the recommended values are N1 = N2 = 2FH. For E1 mode, the recommended values are N1 = N2 = FFH. PROPRIETARY AND CONFIDENTIAL 140 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: 50 AM PMC-1970624 PROPRIETARY AND CONFIDENTIAL 141 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X :2 Default 20 07 01 Function t, Type R/W CENT 0 Bit 3 R/W UNDE 0 Bit 2 R/W OVRE Bit 1 R/W FIFORST Bit 0 R/W LIMIT ug us Bit 4 2A Bit 6: Register 017H: RJAT Configuration 0 sd ay ,0 0 Th ur CENT: 1 d of bn ha cir o on The CENT bit allows the FIFO to self-center its read pointer, maintaining the pointer at least 4 UI away from the FIFO being empty or full. When CENT is set to logic 1, the FIFO is enabled to self-center for the next 384 transmit data bit period, and for the first 384 bit periods following an overrun or underrun event. If an EMPTY or FULL alarm occurs during this 384 UI period, the period will be extended by the number of UI that the EMPTY or FULL alarm persists. During the EMPTY or FULL alarm conditions, data is lost. When CENT is set to logic 0, the self-centering function is disabled, allowing the data to pass through uncorrupted during EMPTY or FULL alarm conditions. ra s ha The recommended value of CENT is logic 1. UNDE: by OVRE: ab do u Setting the UNDE bit to logic 1 enables an underrun event to assert the INTB output low. oa d ed Setting the OVRE bit to logic 1 enables an overrun event to assert the INTB output low. Do wn l FIFORST: Setting the FIFORST bit allows the FIFO to reset when the PLL is reset by software. When FIFORST is logic 1, writing to the PLL Divider Control Registers N1 and N2 will cause both the PLL and FIFO to reset. When PROPRIETARY AND CONFIDENTIAL 142 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 FIFORST is logic 0, writing to the Divider Control Registers N1 and N2 will cause only the PLL to reset. 01 :2 LIMIT: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ug ,0 2A The recommended value of LIMIT is logic 0. us t, 20 07 Setting the LIMIT bit to logic 1 will limit the PLL jitter attenuation by enabling the FIFO to increase or decrease the frequency of the smooth output clock whenever the FIFO is within one UI of overflowing or underflowing. This limiting of jitter ensures that no data is lost during high phase shift conditions. When LIMIT is set to logic 0, underflows and overflows may occur. PROPRIETARY AND CONFIDENTIAL 143 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused 2A R OVRI Bit 0 R UNDI 01 07 20 t, us ug X X ,0 Bit 1 :2 Function ay Type sd Bit 6: Register 018H: TJAT Interrupt Status Th ur UNDI: X cir o on The UNDI bit is asserted when an attempt is made to read data from the transmit FIFO when the FIFO is already empty. When UNDI is a logic 1, an underrun event has occurred. Reading this register will clear the UNDI bit to logic 0. ha OVRI: Do wn l oa d ed by ab do u ra s ha d of bn The OVRI bit is asserted when an attempt is made to write data into the transmit FIFO when the FIFO is already full. When OVRI is a logic 1, an overrun event has occurred. Reading this register will clear the OVRI bit to logic 0. PROPRIETARY AND CONFIDENTIAL 144 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W N1[7] 0 Bit 6 R/W N1[6] 0 Bit 5 R/W N1[5] 1 Bit 4 R/W N1[4] 0 Bit 3 R/W N1[3] 1 Bit 2 R/W N1[2] Bit 1 R/W N1[1] Bit 0 R/W N1[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 019H: TJAT Jitter Attenuator Divider N1 Control 1 sd ay ,0 1 1 cir o on Th ur This register contains an 8-bit binary number, N1, which is one less than the magnitude of the reference clock divisor. The reference divisor magnitude, (N1+1), is the ratio between the frequency of the reference clock (as selected by the PLLREF1 and PLLREF0 bits of the Transmit Timing Options register) and the frequency at the phase discriminator input. of bn ha Writing to this register will reset the PLL. If the FIFORST bit of the TJAT Configuration register is set high, a write to this register will reset both the PLL and FIFO. Do wn l oa d ed by ab do u ra s ha d The default value of N1 after a device reset is 47 = 2FH. PROPRIETARY AND CONFIDENTIAL 145 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W N2[7] 0 Bit 6 R/W N2[6] 0 Bit 5 R/W N2[5] 1 Bit 4 R/W N2[4] 0 Bit 3 R/W N2[3] 1 Bit 2 R/W N2[2] Bit 1 R/W N2[1] Bit 0 R/W N2[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 01AH: TJAT Divider N2 Control 1 sd ay ,0 1 1 o on Th ur This register contains an 8-bit binary number, N2, which is one less than the magnitude of the output clock divisor. The output clock divisor magnitude, (N2+1), is the ratio between the frequency of the smooth output clock and the frequency applied to the phase discriminator input. bn ha cir Writing to this register will reset the PLL. If the FIFORST bit of the TJAT Configuration register is set high, a write to this register will reset both the PLL and FIFO. of The default value of N2 after a device reset is 47 = 2FH. ha d Recommendations ab do u ra s In general, the relationship Fref/(N1+1) = Fout/(N2+1) must always be true in order for the PLL to operate correctly. by Minimizing the values of N1 and N2 while keeping the above equation true minimizes intrinsic jitter. However, the minimum valid value for N2 is 1FH. Do wn l oa d ed In order to meet jitter transfer specifications for some modes, such as basic E1 operation, N1 and N2 must be large in order to reduce the PLL transfer cutoff frequency. In general, for E1 operation, N2 is set to FFH to meet ETSI jitter transfer specifications. When dealing with extremely low frequency references, such as an 8kHz reference clock, the N1 and N2 should configured so that Fref/(N1+1) and Fout/(N2+1) are both 8kHz results. Thus, for an 8kHz reference, N1 is 00H. PROPRIETARY AND CONFIDENTIAL 146 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 The table below summarizes the recommended values for N1 and N2 for common modes of operation. PLL Output Frequency N1[7:0] N2[7:0] 1.544 MHz 1.544 MHz (T1) 2FH 2.048 MHz 2.048 MHz (E1) FFH 2.048 MHz 1.544 MHz (T1) FFH C0H 1.544 MHz 2.048 MHz (E1) C0H FFH nominal 1.544 MHz (derived from gapped 2.048 MHz)1 1.544 MHz (T1) C0H C0H 8 kHz 1.544 MHz (T1) 00H C0H 16 kHz 1.544 MHz (T1) 01H C0H 8 kHz 2.048 MHz (E1) 00H FFH 16 kHz 2.048 MHz (E1) 01H FFH 2FH FFH cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 PLL Reference, as set by register bits PLLREF[1:0] 1 Do wn l oa d ed by ab do u ra s ha d of bn ha Nominal 1.544 MHz is derived from a gapped 2.048 MHz when in T1 mode with the BTIF's RATE[1:0] bits set to "01", "10", or "11" and BTCLK configured as the reference. PROPRIETARY AND CONFIDENTIAL 147 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X :2 Default 20 07 01 Function t, Type R/W CENT 0 Bit 3 R/W UNDE 0 Bit 2 R/W OVRE Bit 1 R/W FIFORST Bit 0 R/W LIMIT ug us Bit 4 2A Bit 6: Register 01BH: TJAT Configuration 0 sd ay ,0 0 Th ur CENT: 1 d of bn ha cir o on The CENT bit allows the FIFO to self-center its read pointer, maintaining the pointer at least 4 UI away from the FIFO being empty or full. When CENT is set to logic 1, the FIFO is enabled to self-center for the next 384 transmit data bit period, and for the first 384 bit periods following an overrun or underrun event. If an EMPTY or FULL alarm occurs during this 384 UI period, the period will be extended by the number of UI that the EMPTY or FULL alarm persists. During the EMPTY or FULL alarm conditions, data is lost. When CENT is set to logic 0, the self-centering function is disabled, allowing the data to pass through uncorrupted during EMPTY or FULL alarm conditions. ra s ha The recommended value of CENT is logic 1. UNDE: by OVRE: ab do u Setting the UNDE bit to logic 1 enables an underrun event to assert the INTB output low. oa d ed Setting the OVRE bit to logic 1 enables an overrun event to assert the INTB output low. Do wn l FIFORST: Setting the FIFORST bit allows the FIFO to reset when the PLL is reset by software. When FIFORST is logic 1, writing to the PLL Divider Control Registers N1 and N2 will cause both the PLL and FIFO to reset. When PROPRIETARY AND CONFIDENTIAL 148 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 FIFORST is logic 0, writing to the Divider Control Registers N1 and N2 will cause only the PLL to reset. 01 :2 LIMIT: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ug ,0 2A The recommended value of LIMIT is logic 0. us t, 20 07 Setting the LIMIT bit to logic 1 will limit the PLL jitter attenuation by enabling the FIFO to increase or decrease the frequency of the smooth output clock whenever the FIFO is within one UI of overflowing or underflowing. This limiting of jitter ensures that no data is lost during high phase shift conditions. When LIMIT is set to logic 0, underflows and overflows may occur. PROPRIETARY AND CONFIDENTIAL 149 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W Reserved 0 Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 0 R/W OR 01 07 20 t, us ug 1 ,0 IR ay R/W X sd Bit 1 :2 Bit 2A 6: Register 01CH: RX-ELST Configuration Th ur Reserved: 1 on This bit must be a logic 0 for correct operation. o IR: ha cir The IR bit selects the input frame format. The IR bit must be set to logic 1 for E1 mode; it must be logic 0 for T1 mode. bn OR: Do wn l oa d ed by ab do u ra s ha d of The OR bit selects the output frame format. The OR bit must be set to logic 1 for E1 mode; it must be logic 0 for T1 mode. PROPRIETARY AND CONFIDENTIAL 150 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X SLIPE Bit 1 R SLIPD Bit 0 R SLIPI 07 20 t, us ug 2A R/W 0 X ,0 Bit 2 :2 Default 01 Function ay Type sd Bit 6: Register 01DH: RX-ELST Interrupt Enable/Status Th ur SLIPE: X cir o on The SLIPE bit position is an interrupt enable that when set, enables the INTB output to assert low when a slip occurs. When the block is reset the SLIPE bit position is cleared and interrupt generation is disabled. ha SLIPD: ha d of bn The SLIPD bit indicates the direction of the last slip. If the SLIPD bit is a logic 1 then the last slip was due to the frame buffer becoming full; a frame was deleted. If the SLIPD bit is a logic 0 then the last slip was due to the frame buffer becoming empty; a frame was duplicated. ra s SLIPI: Do wn l oa d ed by ab do u The SLIPI bit is set if a slip occurred since the last read of this register. The SLIPI bit is cleared upon reading this register. PROPRIETARY AND CONFIDENTIAL 151 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W D7 1 Bit 6 R/W D6 1 Bit 5 R/W D5 1 Bit 4 R/W D4 1 Bit 3 R/W D3 1 Bit 2 R/W D2 Bit 1 R/W D1 Bit 0 R/W D0 ug us t, 20 07 01 :2 Bit 2A 6: Register 01EH: RX-ELST Idle Code 1 sd ay ,0 1 1 cir o on Th ur The contents of this register replace the timeslot data in the BRPCM serial data stream when the framer is out of frame and the TRKEN bit in the Receive Options register is a logic 1. Since the transmission of all ones timeslot data is a common requirement, this register is set to all ones on a reset condition. D7 is the first to be transmitted. Do wn l oa d ed by ab do u ra s ha d of bn ha The writing of the idle code pattern is asynchronous with respect to the output data clock. One timeslot of idle code data will be corrupted if the register is written to when the framer is out of frame. PROPRIETARY AND CONFIDENTIAL 152 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W Reserved 0 Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 0 R/W OR 01 07 20 t, us ug 1 ,0 IR ay R/W X sd Bit 1 :2 Bit 2A 6: Register 020H: TX-ELST Configuration Th ur Reserved: 1 on This bit must be programmed to logic 0 for correct operation. o IR: ha cir The IR bit selects the input frame format. The IR bit must be set to logic 1 for E1 mode; it must be logic 0 for T1 mode. bn OR: Do wn l oa d ed by ab do u ra s ha d of The OR bit selects the output frame format. The OR bit must be set to logic 1 for E1 mode; it must be logic 0 for T1 mode. PROPRIETARY AND CONFIDENTIAL 153 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X SLIPE Bit 1 R SLIPD Bit 0 R SLIPI 07 20 t, us ug 2A R/W 0 X ,0 Bit 2 :2 Default 01 Function ay Type sd Bit 6: Register 021H: TX-ELST Interrupt Enable/Status Th ur SLIPE: X cir o on The SLIPE bit position is an interrupt enable that when set, enables the INTB output to assert low when a slip occurs. When the block is reset the SLIPE bit position is cleared and interrupt generation is disabled. ha SLIPD: ha d of bn The SLIPD bit indicates the direction of the last slip. If the SLIPD bit is a logic 1 then the last slip was due to the frame buffer becoming full; a frame was deleted. If the SLIPD bit is a logic 0 then the last slip was due to the frame buffer becoming empty; a frame was duplicated. ra s SLIPI: Do wn l oa d ed by ab do u The SLIPI bit is set if a slip occurred since the last read of this register. The SLIPI bit is cleared upon reading this register. PROPRIETARY AND CONFIDENTIAL 154 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL1_EVEN 0 Bit 6 R/W DL1_ODD 0 Bit 5 R/W T1_DL_EN 1 Bit 4 R/W DL1_TS[4] 0 Bit 3 R/W DL1_TS[3] 0 Bit 2 R/W DL1_TS[2] Bit 1 R/W DL1_TS[1] Bit 0 R/W DL1_TS[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 028H: RXCE Receive Data Link 1 Control 0 sd ay ,0 0 0 o on Th ur This register, along with the RXCE Data Link 1 Bit Select register, controls the extraction of the data link terminated by RDLC #1. Refer to the "Using the Internal HDLC Receivers" description in the Operation section for details on terminating HDLC frames. cir DL1_EVEN: ab do u DL1_ODD: ra s ha d of bn ha The data link 1 even select (DL1_EVEN) bit controls whether or not the first data link is extracted from the even frames of the receive data stream. If DL1_EVEN is a logic 0, the data link is not extracted from the even frames. If DL1_EVEN is a logic 1, the data link is extracted from the even frames. In E1 mode, the frames in an E1 CRC-4 multiframe are considered to be numbered from 0 to 15; in T1 mode, the frames in a superframe are considered to be numbered from 1 to 12 (or 1 to 24 in an extended superframe). ed by The data link 1 odd select (DL1_ODD) bit controls whether or not the first data link is extracted from the odd frames of the receive data stream. If DL1_ODD is a logic 0, the data link is not extracted from the odd frames. If DL1_ODD is a logic 1, the data link is extracted from the odd frames. Do wn l oa d T1_DL_EN: The T1 data link enable bit allows the termination of the ESF or T1DM data links when in T1 mode. If T1_DL_EN is a logic 1, the ESF, FMS1 and FMS0 bits of the T1 FRMR Configuration register determine the bit locations from which the data link is extracted. When the T1_DL_EN bit is a logic 1, the PROPRIETARY AND CONFIDENTIAL 155 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 DL1_EVEN and DL1_ODD bits must both be set to logic 0. This bit must be set to logic 0 when in E1 mode. 01 :2 DL1_TS[4:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 The data link 1 time slot (DL1_TS[4:0]) bits gives a binary representation of the time slot/channel from which the data link is to be extracted. Note that T1 channels 1 to 24 are mapped to values 0 to 23. The DL1_TS[4:0] bits have no effect when DL1_EVEN and DL1_ODD are both a logic 0. PROPRIETARY AND CONFIDENTIAL 156 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL1_BIT[7] 0 Bit 6 R/W DL1_BIT[6] 0 Bit 5 R/W DL1_BIT[5] 0 Bit 4 R/W DL1_BIT[4] 0 Bit 3 R/W DL1_BIT[3] 0 Bit 2 R/W DL1_BIT[2] Bit 1 R/W DL1_BIT[1] Bit 0 R/W DL1_BIT[0] 01 07 20 t, us ug 0 sd ay ,0 0 0 Th ur DL1_BIT[7:0]: :2 Bit 2A 6: Register 029H: RXCE Receive Data Link 1 Bit Select Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The data link 1 bit select (DL1_BIT[7:0]) bits controls which bits of the time slot/channel are to be extracted and passed to RDLC #1. If DL1_BIT[x] is a logic 1, that bit is extracted as part of the data link. To extract the data link from the entire time slot, all eight DL1_BIT[x] bits must be set to a logic 1. DL1_BIT[7] corresponds to the most significant bit (bit 1, the first bit received) of the time slot and DL1_BIT[0] corresponds to the least significant bit (bit 8, the last bit received) of the time slot. The DL1_BIT[7:0] bits have no effect when the DL1_EVEN and DL1_ODD bits of the RXCE Data Link 1 Control register are both logic 0. PROPRIETARY AND CONFIDENTIAL 157 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL2_EVEN 0 Bit 6 R/W DL2_ODD 0 Bit 5 R/W Unused X Bit 4 R/W DL2_TS[4] 0 Bit 3 R/W DL2_TS[3] 0 Bit 2 R/W DL2_TS[2] Bit 1 R/W DL2_TS[1] Bit 0 R/W DL2_TS[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 02AH: RXCE Receive Data Link 2 Control 0 sd ay ,0 0 0 o on Th ur This register, along with the RXCE Data Link 2 Bit Select register, controls the extraction of the data link terminated by RDLC #2. Refer to the "Using the Internal HDLC Receivers" description in the Operation section for details on terminating HDLC frames. cir DL2_EVEN: ab do u ra s ha d of bn ha The data link 2 even select (DL2_EVEN) bit controls whether or not the second data link is extracted from the even frames of the receive data stream. If DL2_EVEN is a logic 0, the data link is not extracted from the even frames. If DL2_EVEN is a logic 1, the data link is extracted from the even frames. In E1 mode, the frames in an E1 CRC-4 multiframe are considered to be numbered from 0 to 15; in T1 mode, the frames in a superframe are considered to be numbered from 1 to 12 (or 1 to 24 in an extended superframe). DL2_ODD: oa d ed by The data link 2 odd select (DL2_ODD) bit controls whether or not the second data link is extracted from the odd frames of the receive data stream. If DL2_ODD is a logic 0, the data link is not extracted from the odd frames. If DL2_ODD is a logic 1, the data link is extracted from the odd frames. Do wn l DL2_TS[4:0]: The data link 2 time slot (DL2_TS[4:0]) bits gives a binary representation of the time slot/channel from which the data link is to be extracted. Note that T1 channels 1 to 24 are mapped to values 0 to 23. The DL2_TS[4:0] bits have no effect when DL2_EVEN and DL2_ODD are both a logic 0. PROPRIETARY AND CONFIDENTIAL 158 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL2_BIT[7] 0 Bit 6 R/W DL2_BIT[6] 0 Bit 5 R/W DL2_BIT[5] 0 Bit 4 R/W DL2_BIT[4] 0 Bit 3 R/W DL2_BIT[3] 0 Bit 2 R/W DL2_BIT[2] Bit 1 R/W DL2_BIT[1] Bit 0 R/W DL2_BIT[0] 01 07 20 t, us ug 0 sd ay ,0 0 0 Th ur DL2_BIT[7:0]: :2 Bit 2A 6: Register 02BH: RXCE Receive Data Link 2 Bit Select Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The data link 2 bit select (DL2_BIT[7:0]) bits controls which bits of the time slot/channel are to be extracted and passed to RDLC #2. If DL2_BIT[x] is a logic 1, that bit is extracted as part of the data link. To extract the data link from the entire time slot, all eight DL2_BIT[x] bits must be set to a logic 1. DL2_BIT[7] corresponds to the most significant bit (bit 1, the first bit received) of the time slot and DL2_BIT[0] corresponds to the least significant bit (bit 8, the last bit received) of the time slot. The DL2_BIT[7:0] bits have no effect when the DL2_EVEN and DL2_ODD bits of the RXCE Data Link 2 Control register are both logic 0. PROPRIETARY AND CONFIDENTIAL 159 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL3_EVEN 0 Bit 6 R/W DL3_ODD 0 Bit 5 R/W Unused X Bit 4 R/W DL3_TS[4] 0 Bit 3 R/W DL3_TS[3] 0 Bit 2 R/W DL3_TS[2] Bit 1 R/W DL3_TS[1] Bit 0 R/W DL3_TS[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 02CH: RXCE Receive Data Link 3 Control 0 sd ay ,0 0 0 o on Th ur This register, along with the RXCE Data Link 3 Bit Select register, controls the extraction of the data link terminated by RDLC #3. Refer to the "Using the Internal HDLC Receivers" description in the Operation section for details on terminating HDLC frames. cir DL3_EVEN: ab do u DL3_ODD: ra s ha d of bn ha The data link 3 even select (DL3_EVEN) bit controls whether or not the third data link is extracted from the even frames of the receive data stream. If DL3_EVEN is a logic 0, the data link is not extracted from the even frames. If DL3_EVEN is a logic 1, the data link is extracted from the even frames. In E1 mode, the frames in an E1 CRC-4 multiframe are considered to be numbered from 0 to 15; in T1 mode, the frames in a superframe are considered to be numbered from 1 to 12 (or 1 to 24 in an extended superframe). ed by The data link 3 odd select (DL3_ODD) bit controls whether or not the third data link is extracted from the odd frames of the receive data stream. If DL3_ODD is a logic 0, the data link is not extracted from the odd frames. If DL3_ODD is a logic 1, the data link is extracted from the odd frames. Do wn l oa d DL3_TS[4:0]: The data link 3 time slot (DL3_TS[4:0]) bits gives a binary representation of the time slot/channel from which the data link is to be extracted. Note that T1 channels 1 to 24 are mapped to values 0 to 23. The DL3_TS[4:0] bits have no effect when DL3_EVEN and DL3_ODD are both a logic 0. PROPRIETARY AND CONFIDENTIAL 160 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL3_BIT[7] 0 Bit 6 R/W DL3_BIT[6] 0 Bit 5 R/W DL3_BIT[5] 0 Bit 4 R/W DL3_BIT[4] 0 Bit 3 R/W DL3_BIT[3] 0 Bit 2 R/W DL3_BIT[2] Bit 1 R/W DL3_BIT[1] Bit 0 R/W DL3_BIT[0] 01 07 20 t, us ug 0 sd ay ,0 0 0 Th ur DL3_BIT[7:0]: :2 Bit 2A 6: Register 02DH: RXCE Receive Data Link 3 Bit Select Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The data link 3 bit select (DL3_BIT[7:0]) bits controls which bits of the time slot/channel are to be extracted and passed to RDLC #3. If DL3_BIT[x] is a logic 1, that bit is extracted as part of the data link. To extract the data link from the entire time slot, all eight DL3_BIT[x] bits must be set to a logic 1. DL3_BIT[7] corresponds to the most significant bit (bit 1, the first bit received) of the time slot and DL3_BIT[0] corresponds to the least significant bit (bit 8, the last bit received) of the time slot. The DL3_BIT[7:0] bits have no effect when the DL3_EVEN and DL3_ODD bits of the RXCE Data Link 3 Control register are both logic 0. PROPRIETARY AND CONFIDENTIAL 161 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W NXDS0[1] 0 Bit 6 R/W NXDS0[0] 0 Bit 5 R/W CMODE 1 Bit 4 R/W DE 1 Bit 3 R/W FE 1 Bit 2 R/W CMS Bit 1 R/W RATE[1] Bit 0 R/W RATE[0] :2 Type 2A ug us t, 20 07 01 Bit 6: Register 030H: BRIF Configuration 0 ,0 ay sd 0 Th ur NXDS0[1:0]: 0 - Receive Backplane NXDS0 Mode Selection NXDS0[0] 0 0 0 1 of d 64 kbit/s NxDS0 1 64 kbit/s NxDS0 with F-bit (only valid for E1 mode) ha 0 ab do u 1 Full Frame 56 kbit/s NxDS0 ra s 1 Operation bn NXDS0[1] ha Table 21 cir o on The NXDS0[1:0] bits determine the mode of operation when BRCLK clock master mode is selected, as shown in the following table. Note that these bits are ignored when clock slave mode is selected. by When in Full Frame mode, the entire frame (193 bits for T1 or 256 bits for E1) is presented and the BRCLK pulse train contains no gaps. Do wn l oa d ed When in any of the NxDS0 modes, only those time slots with their DTRKC bit cleared (logic 0) are clocked out the backplane. BRCLK does not pulse during those time slots with their DTRKC bit set (logic 1). The DTRKC bits are located in the RPSC Indirect Registers. When in T1 mode, the clock is always gapped during the framing bit position. When the 56 kbit/s NxDS0 mode is selected, only the first 7 bits of the selected time slots are presented to the backplane and the 8th bit is gapped out. When PROPRIETARY AND CONFIDENTIAL 162 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 the 64 kbit/s NxDS0 mode is selected, all 8 bits of the selected time slots are presented to the backplane. ug us t, 20 07 01 :2 The 64 kbit/s NxDS0 with F-bit mode is intended to support ITU recommendation G.802 where 1.544 Mbit/s data is carried within a 2.048 Mbit/s data stream. This mode is only valid when the E1/T1B register bit is a logic 1 (E1 mode is selected). The operation is the same as the 64 NxDS0 mode, except that the framing bit is presented during the first bit of time slot 26. To properly extract a G.802 formatted T1, the DTRKC bits must be set to logic 0 for time slots 1 through 15 and 17 through 26, and the DTRKC bits must be set to logic 1 for time slots 27 through 31. 2A CMODE: o on Th ur sd ay ,0 The clock mode (CMODE) bit determines whether the BRCLK pin is an input or output. When CMODE is a logic 0, clock master mode is selected and the BRCLK output is derived from the integral clock synthesizer. Depending on the mode of operation, BRCLK may have a burst frequency of up to 2.048 MHz and may be gapped to support sub-rate applications. In T1 mode, CMODE can only be logic 0 if the backplane rate is 1.544 Mbit/s (RATE[1:0]=00) and CMS=0. In E1 mode, CMODE can only be logic 0 if the backplane rate is 2.048 Mbit/s (RATE[1:0]=01) and CMS=0. ha cir When CMODE is a logic 1, clock slave mode is selected and BRCLK is an input. bn DE: ra s ha d of The data edge (DE) bit determines the edge of BRCLK on which BRPCM and BRSIG are generated. If DE is a logic 0, BRPCM and BRSIG are updated on the falling edge of BRCLK. If DE is a logic 1, BRPCM and BRSIG are updated on the rising edge of BRCLK. ab do u FE: oa d ed by The framing edge (FE) bit determines the edge of BRCLK on which the frame pulse (BRFP) pulse is sampled or updated. If FE is a logic 0, BRFP is sampled or updated on the falling edge of BRCLK. If FE is a logic 1, BRFP is sampled on the rising edge of BRCLK. In the case where FE is not equal to DE, BRFP is sampled or updated one clock edge before BRPCM and BRSIG. Do wn l CMS: The clock mode select (CMS) bit determines the BRCLK frequency multiple. If CMS is a logic 0, BRCLK is at the backplane rate. If CMS is a logic 1, BRCLK is at twice the backplane rate. PROPRIETARY AND CONFIDENTIAL 163 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 RATE[1:0]: RATE[0] Backplane Rate 0 0 1.544 Mbit/s 0 1 2.048 Mbit/s 1 0 4.096 Mbit/s 1 1 8.192 Mbit/s ,0 2A ug us t, RATE[1] 07 - Receive Backplane Rate 20 Table 22 01 :2 6: The rate select (RATE[1:0]) bits determine the backplane rate according to the following table: ur sd ay The 4.096 Mbit/s and 8.192 Mbit/s rates are only supported in clock slave mode (CMODE logic 1) with RXELSTBYP logic 0. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th The RATE[1:0] bits can only be set once after reset. PROPRIETARY AND CONFIDENTIAL 164 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W MAP 0 Bit 6 R/W FPINV 0 Bit 5 R/W FPMODE 1 Bit 4 R/W ALTFDL 0 Bit 3 R/W ROHM 0 Bit 2 R/W BRXSMFP Bit 1 R/W BRXCMFP Bit 0 R/W ALTBRFP 07 20 t, us ug 2A 0 sd ay ,0 0 0 Th ur MAP: :2 Type 01 Bit 6: Register 031H: BRIF Frame Pulse Configuration cir o on The MAP bit determines the mapping of a 2.048 MHz backplane onto a 1.544 MHz line. This bit is ignored when in E1 mode (E1/T1B register bit is logic 1), when the backplane rate is 1.544 Mbit/s (RATE[1:0] = 'b00), or when in clock master mode (CMODE = 'b0). of bn ha When MAP is a logic 0, every fourth time slot is unused, starting with time slot 0. The framing bit is presented during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are unused. ab do u FPINV: ra s ha d When MAP is a logic 1, the first 24 time slots (0 to 23) are used. The framing bit is sampled during bit 7 of time slot 31 and the rest of the frame (time slots 24 to 30 and bits 0 to 6 of time slot 31) does not contain valid data. by The frame pulse inversion (FPINV) bit determines whether BRFP is inverted prior to sampling or presentation. If FPINV is a logic 0, BRFP is active high. If FPINV is a logic 1, BRFP is active low. ed FPMODE: Do wn l oa d The frame pulse mode (FPMODE) bit determines whether BRFP is an input or an output. When FPMODE is a logic 0, frame pulse master mode is selected, BRFP is an output and the ROHM, BRXSMFP, BRXCMFP and ALTBRFP bits determine what BRFP connotes. PROPRIETARY AND CONFIDENTIAL 165 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 When FPMODE is a logic 1, frame pulse slave mode is selected and BRFP is an input. When configured as an input, BRFP only has effect when the elastic store is in use (RXELSTBYP is logic 0); otherwise, it is ignored. 01 ALTFDL: ,0 2A ug us t, 20 07 In T1 mode, the ALTFDL bit enables the framing bit position on the backplane PCM output to contain a copy of the FDL bit. When ALTFDL is set to logic 1, each M-bit value in the ESF-formatted stream is duplicated and replaces the subsequent CRC bit or F-bit in the output signal stream on BRPCM. When ALTFDL is set to logic 0, the output BRPCM stream contains the received M, CRC, or F bits in the framing bit position. Note that this function is only valid for ESF-formatted streams, ALTFDL should be set to logic 0 when other framing formats are being received. sd ay This bit is ignored in E1 mode. ur ALTBRFP: ra s ha d of bn ha cir o on Th The ALTBRFP bit suppresses every second output pulse on the backplane output BRFP. When ALTBRFP is set to logic 1 and BRXCMFP and BRXSMP bits are both logic 0, the output signal on BRFP pulses every 386 bits or 512 bits, indicating the first bit of every second frame. Under this condition, BRFP indicates the Signaling Alignment bits (S1-S6) for T1 SF, the data link bits for T1 ESF and the NFAS frames for E1. If the BRXCMFP or BRXSMFP bit is logic 1 when ALTBRFP is logic 1, the output signal on BRFP pulses every 24, 32 or 48 frames. In T1 mode, this latter setting (i.e. both ALTBRFP and BRXSMFP set to logic 1) is useful for converting SF formatted data to ESF formatted data between two COMET devices. When ALTBRFP is set to logic 0, the output signal on BRFP pulses in accordance to the ROHM, BRXCMFP and BRXSMP bit settings. Do wn l oa d ed by ab do u ALTBRFP has no effect if the FPMODE bit or the ROHM bit is a logic 1. PROPRIETARY AND CONFIDENTIAL 166 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 ROHM, BRXSMFP, BRXCMFP: 07 01 :2 The ROHM, BRXSMFP and BRXCMFP bits select the output signal seen on the backplane output BRFP. These register bits only have effect if the FPMODE bit is a logic 0. 2A ug us t, 20 In T1 mode, only BRXSMFP has effect, the other two bits are ignored. When set to logic 1, the BRFP output pulses high during the first framing bit of the 12 frame SF or the 24 frame ESF (depending on the framing format selected in the T1-FRMR ). When BRXSMFP is set to logic 0, the BRFP output pulses high during each framing bit (i.e. every 193 bits). ,0 The following table summarizes the configurations for E1 mode: - E1 Receive Backplane Frame Pulse Configurations sd ay Table 23 BRXSMFP BRXCMFP Result 0 0 0 Backplane receive frame pulse output: Th ur ROHM cir o on BRFP pulses high for 1 BRCLK cycle during bit 1 of each 256-bit frame, indicating the frame alignment of the BRPCM data stream. 1 Backplane receive CRC multiframe output: ha 0 BRFP pulses high for 1 BRCLK cycle during bit 1 of frame 1 of every 16 frame CRC multiframe, indicating the CRC multiframe alignment of the BRPCM data stream. (Even when CRC multiframing is disabled, the BRFP output continues to indicate the position of bit 1 of the FAS frame every 16th frame). ab do u ra s ha d of bn 0 1 0 Backplane receive signaling multiframe output: by 0 Do wn l oa d ed BRFP pulses high for 1 BRCLK cycle during bit 1 of frame 1 of the 16 frame signaling multiframe, indicating the signaling multiframe alignment of the BRPCM data stream. (Even when signaling multiframing is disabled, the BRFP output continues to indicate the position of bit 1 of every 16th frame.) PROPRIETARY AND CONFIDENTIAL 167 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 BRXSMFP BRXCMFP Result 0 1 1 Backplane receive composite multiframe output: 01 :2 6: 50 ROHM Backplane receive overhead output: o X cir X BRFP is high for timeslot 0 and timeslot 16 of each 256-bit frame, indicating the overhead of the BRPCM data stream. Do wn l oa d ed by ab do u ra s ha d of bn ha 1 on Th ur sd ay ,0 2A ug us t, 20 07 BRFP goes high on the active BRCLK edge marking the beginning of bit 1 of frame 1 of every 16 frame signaling multiframe, indicating the signaling multiframe alignment of the BRPCM data stream, and returns low on the active BRCLK edge marking the end of bit 1 of frame 1 of every 16 frame CRC multiframe, indicating the CRC multiframe alignment of the BRPCM data stream. This mode allows both multiframe alignments to be decoded externally from the single BRFP signal. Note that if the signaling and CRC multiframe alignments are coincident, BRFP will pulse high for 1 BRCLK cycle every 16 frames. PROPRIETARY AND CONFIDENTIAL 168 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W RPTYP 0 Bit 6 R/W RPTYE 0 Bit 5 R/W FIXF 0 Bit 4 R/W FIXPOL 0 Bit 3 R/W PTY_EXTD 0 TRI[1] Bit 0 R/W TRI[0] 07 20 t, us 0 ,0 R/W X ay Bit 1 ug 2A Unused sd Bit 2 :2 Type 01 Bit 6: Register 032H: BRIF Parity/F-bit Configuration 0 ra s RPTYP: ha d of bn ha cir o on Th ur This register provides control of data integrity checking on the receive backplane interface. A single parity bit in the F-bit position represents parity over the previous frame (including the undefined bit positions). If a 2.048 Mbit/s backplane rate is selected, the parity calculation is performed over all bit positions, including the undefined positions. Signaling parity is similarly calculated over all bit positions. Parity checking and generation is not supported when the NxDS0 mode is active. Parity checking and generation is not supported when mapping a 1.544 Mbit/s signal onto a higher rate backplane in the format where the first 24 time slots are used, i.e., the RATE[1:0] bits in the BRIF Configuration register are not set to "00" and the MAP bit in the BRIF Frame Pulse Configuration register is logic 1. oa d ed by ab do u The receive parity type (RPTYP) bit sets even or odd parity in the receive streams. If RPTYP is a logic 0, the expected parity value in the F-bit position of BRPCM and BRSIG is even, thus it is a one if the number of ones in the previous frame is odd. If RPTYP is a logic 1, the expected parity value in the F-bit position if BRPCM and BRSIG is odd, thus it is a one if the number of ones in the previous frame is even. RPTYP only has effect if RPRTYE is a logic one. Do wn l RPRTYE: The RPRTYE bit enables receive parity insertion. When set a logic one, parity is inserted into the F-bit position of the BRPCM and BRSIG streams. When set to logic zero, the F-bit passes through transparently. PROPRIETARY AND CONFIDENTIAL 169 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 FIXF: 01 :2 6: If the RPRTYE bit is a logic 0, a logic 1 in the FIXF bit forces the first bit of the BRPCM frame (F-bit for T1) to the polarity specified by the FIXPOL bit. 20 07 If RPRTYE is a logic 1, FIXF has no effect. If RPRTYE and FIXF are both logic 0, the first bit of the frame passes from the line transparently. t, FIXPOL: ,0 2A ug us This bit determines the logic level of the first bit of the BRPCM frame when the FIXF bit is a logic 1 and the RPRTYE bit is a logic 0. If FIXPOL is a logic 1, BRPCM will be high in the first bit of the frame. If FIXPOL is a logic 0, BRPCM will be low in the first bit of the frame. ay PTY_EXTD: on Th ur sd The parity extend (PRY_EXTD) bit determines the scope of the parity calculation. When PTY_EXTD is logic 1, the parity is calculated over the previous frame plus the previous parity bit. When it is logic 0, the parity is calculated only over the previous frame. TRI[1:0]: ha cir o The tri-state control bits determine when the BRPCM and BRSIG outputs are high impedance. - Receive Backplane Tri-state Control bn Table 24 TRI[0] Effect 0 0 0 1 d ha ra s ab do u by oa d Totem-pole operation. BRPCM and BRSIG drive during the bit periods that contain valid data, i.e. every second or fourth byte for multiplexed operation. Open-drain operation. BRPCM and BRSIG are driven low to indicate a zero. BRPCM and BRSIG are high impedance otherwise. 1 Reserved Do wn l 1 BRPCM and BRSIG are held high impedance. This default ensures the outputs are high impedance during reset and configuration 0 ed 1 of TRI[1] PROPRIETARY AND CONFIDENTIAL 170 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R/W TSOFF[6] 0 Bit 5 R/W TSOFF[5] 0 Bit 4 R/W TSOFF[4] 0 Bit 3 R/W TSOFF[3] 0 Bit 2 R/W TSOFF[2] Bit 1 R/W TSOFF[1] Bit 0 R/W TSOFF[0] t, us ug 0 sd ay ,0 0 0 Th ur TSOFF[6:0]: 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 033H: BRIF Time Slot Offset Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The time slot offset (TSOFF[6:0]) bits give a binary representation of the fixed byte offset between the backplane receive frame pulse (BRFP) and the start of the next frame on the backplane receive data signal (BRPCM). The seven bits can give an offset from 0 - 127 bytes. With a data rate of 2.048 Mbit/s, every byte on BRPCM is driven. With a data rate of 4.096 Mbit/s, every second byte on BRPCM is driven. With a data rate of 8.192 Mbit/s, every fourth byte on BRPCM is driven. PROPRIETARY AND CONFIDENTIAL 171 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X 0 R/W BOFF[2] Bit 1 R/W BOFF[1] Bit 0 R/W BOFF[0] 07 20 t, 0 0 0 Th ur BOFF_EN: us Bit 2 ug BOFF_EN 2A R/W ,0 Bit 3 :2 Default 01 Function ay Type sd Bit 6: Register 034H: BRIF Bit Offset ha cir o on The bit offset enable (BOFF_EN) bit is used to enable the bit offset bits. If BOFF_EN is a logic 0, the bit offset is disabled and there is no bit offset between the frame pulse and the first bit of the first time slot. In this case, the BOFF[2:0] bits are ignored. If BOFF_EN is a logic 1, the bit offset is enabled and the BOFF[2:0] bits operate as described below. bn BOFF[2:0]: Do wn l oa d ed by ab do u ra s ha d of The bit offset (BOFF[2:0]) bits gives a binary representation of the fixed offset between the backplane receive frame pulse (BRFP) and the start of the first bit of the first time slot. This binary representation is then used to determine the BRCLK edge, defined as CET (clock edge transmit) on which the first bit of the first time slot is sampled. For example, if CET is 4, the data on BRPCM and BRSIG is sampled on the fourth clock edge after BRFP is sampled (see Figure 11). The following tables show the relationship between BOFF[2:0], FE, DE and CER. PROPRIETARY AND CONFIDENTIAL 172 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 6: BOFF[2:0] :2 DE 000 001 010 011 100 101 110 111 0 4 6 8 10 12 14 16 18 0 1 3 5 7 9 11 13 15 17 1 0 3 5 7 9 11 13 15 17 1 1 4 6 8 10 12 14 16 18 t, us ug 2A CET ,0 - Receive Backplane Bit Offset for CMS = 1 BOFF[2:0] ay DE 001 010 011 100 101 110 111 16 20 24 28 32 15 19 23 27 31 ur 000 sd Table 26 FE 20 0 07 FE - Receive Backplane Bit Offset for CMS = 0 01 Table 25 50 AM PMC-1970624 0 4 8 12 0 1 3 7 11 1 0 3 7 11 15 19 23 27 31 1 1 4 8 12 16 20 24 28 32 CET ha cir o on Th 0 of bn The above tables are consistent with the convention established by the Concentration Highway Interface (CHI) specification. Do wn l oa d ed by ab do u ra s ha d Note that in the case where FE is logic 0, DE is logic 1 and BRFP is configured for a superframe/multiframe mode, the maximum offset is one frame less two bits, rather than one frame less one bit as in all other configurations. In this configuration, the maximum offset is 191 bits at 1.544 Mbit/s, 254 bits at 2.048 Mbit/s, 510 bits at 4.096 Mbit/s and 1022 bits at 8.192 Mbit/s. PROPRIETARY AND CONFIDENTIAL 173 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL1_EVEN 0 Bit 6 R/W DL1_ODD 0 Bit 5 R/W T1_DL_EN 1 Bit 4 R/W DL1_TS[4] 0 Bit 3 R/W DL1_TS[3] 0 Bit 2 R/W DL1_TS[2] Bit 1 R/W DL1_TS[1] Bit 0 R/W DL1_TS[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 038H: TXCI Transmit Data Link 1 Control 0 sd ay ,0 0 0 o on Th ur This register, along with the TXCI Data Link 1 Bit Select register, controls the insertion of the data link generated by TDPR #1. Refer to the "Using the Internal HDLC Transmitters" description in the Operation section for details on terminating HDLC frames. cir DL1_EVEN: ab do u DL1_ODD: ra s ha d of bn ha The data link 1 even select (DL1_EVEN) bit controls whether or not the first data link is inserted into the even frames of the receive data stream. If DL1_EVEN is a logic 0, the data link is not inserted into the even frames. If DL1_EVEN is a logic 1, the data link is inserted into the even frames. In E1 mode, the frames in an E1 CRC-4 multiframe are considered to be numbered from 0 to 15; in T1 mode, the frames in a superframe are considered to be numbered from 1 to 12 (or 1 to 24 in an extended superframe). ed by The data link 1 odd select (DL1_ODD) bit controls whether or not the first data link is inserted into the odd frames of the receive data stream. If DL1_ODD is a logic 0, the data link is not inserted into the odd frames. If DL1_ODD is a logic 1, the data link is inserted into the odd frames. Do wn l oa d T1_DL_EN: The T1 data link enable bit allows the generation of the ESF or T1DM data links when in T1 mode. If T1_DL_EN is a logic 1, the ESF, FMS1 and FMS0 bits of the T1 FRMR Configuration register determine the bit locations into which the data link is inserted. When the T1_DL_EN bit is a logic 1, the PROPRIETARY AND CONFIDENTIAL 174 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 DL1_EVEN and DL1_ODD bits must both be set to logic 0. This bit must be set to logic 0 when in E1 mode. 01 :2 DL1_TS[4:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 The data link 1 time slot (DL1_TS[4:0]) bits gives a binary representation of the time slot/channel into which the data link is to be inserted. Note that T1 channels 1 to 24 are mapped to values 0 to 23. The DL1_TS[4:0] bits have no effect when DL1_EVEN and DL1_ODD are both a logic 0. PROPRIETARY AND CONFIDENTIAL 175 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL1_BIT[7] 0 Bit 6 R/W DL1_BIT[6] 0 Bit 5 R/W DL1_BIT[5] 0 Bit 4 R/W DL1_BIT[4] 0 Bit 3 R/W DL1_BIT[3] 0 Bit 2 R/W DL1_BIT[2] Bit 1 R/W DL1_BIT[1] Bit 0 R/W DL1_BIT[0] 01 07 20 t, us ug 0 sd ay ,0 0 0 Th ur DL1_BIT[7:0]: :2 Bit 2A 6: Register 039H: TXCI Transmit Data Link 1 Bit Select Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The data link 1 bit select (DL1_BIT[7:0]) bits controls into which bits of the time slot/channel data from TDPR #1 are to be inserted. If DL1_BIT[x] is a logic 1, the data link is inserted into that bit. To insert the data link into the entire time slot, all eight DL1_BIT[x] bits must be set to a logic 1. DL1_BIT[7] corresponds to the most significant bit (bit 1, the first bit transmitted) of the time slot and DL1_BIT[0] corresponds to the least significant bit (bit 8, the last bit transmitted) of the time slot. The DL1_BIT[7:0] bits have no effect when the DL1_EVEN and DL1_ODD bits of the TXCI Data Link 1 Control register are both logic 0. PROPRIETARY AND CONFIDENTIAL 176 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W DL2_EVEN 0 Bit 6 R/W DL2_ODD 0 Unused X 07 20 t, R/W DL2_TS[4] 0 Bit 3 R/W DL2_TS[3] 0 Bit 2 R/W DL2_TS[2] Bit 1 R/W DL2_TS[1] Bit 0 R/W DL2_TS[0] ug us Bit 4 2A Bit 5 :2 Type 01 Bit 6: Register 03AH: TXCI Transmit Data Link 2 Control 0 sd ay ,0 0 0 o on Th ur This register, along with the TXCI Data Link 2 Bit Select register, controls the insertion of the data link generated by TDPR #2. Refer to the "Using the Internal HDLC Transmitters" description in the Operation section for details on terminating HDLC frames. cir DL2_EVEN: ab do u DL2_ODD: ra s ha d of bn ha The data link 2 even select (DL2_EVEN) bit controls whether or not the second data link is inserted into the even frames of the receive data stream. If DL2_EVEN is a logic 0, the data link is not inserted into the even frames. If DL2_EVEN is a logic 1, the data link is inserted into the even frames. In E1 mode, the frames in an E1 CRC-4 multiframe are considered to be numbered from 0 to 15; in T1 mode, the frames in a superframe are considered to be numbered from 1 to 12 (or 1 to 24 in an extended superframe). ed by The data link 2 odd select (DL2_ODD) bit controls whether or not the second data link is inserted into the odd frames of the receive data stream. If DL2_ODD is a logic 0, the data link is not inserted into the odd frames. If DL2_ODD is a logic 1, the data link is inserted into the odd frames. Do wn l oa d DL2_TS[4:0]: The data link 2 time slot (DL2_TS[4:0]) bits gives a binary representation of the time slot/channel into which the data link is to be inserted. Note that T1 channels 1 to 24 are mapped to values 0 to 23. The DL2_TS[4:0] bits have no effect when DL2_EVEN and DL2_ODD are both a logic 0. PROPRIETARY AND CONFIDENTIAL 177 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL2_BIT[7] 0 Bit 6 R/W DL2_BIT[6] 0 Bit 5 R/W DL2_BIT[5] 0 Bit 4 R/W DL2_BIT[4] 0 Bit 3 R/W DL2_BIT[3] 0 Bit 2 R/W DL2_BIT[2] Bit 1 R/W DL2_BIT[1] Bit 0 R/W DL2_BIT[0] 01 07 20 t, us ug 0 sd ay ,0 0 0 Th ur DL2_BIT[7:0]: :2 Bit 2A 6: Register 03BH: TXCI Transmit Data Link 2 Bit Select Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The data link 2 bit select (DL2_BIT[7:0]) bits controls into which bits of the time slot/channel data from TDPR #2 are to be inserted. If DL2_BIT[x] is a logic 1, the data link is inserted into that bit. To insert the data link into the entire time slot, all eight DL2_BIT[x] bits must be set to a logic 1. DL2_BIT[7] corresponds to the most significant bit (bit 1, the first bit transmitted) of the time slot and DL2_BIT[0] corresponds to the least significant bit (bit 8, the last bit transmitted) of the time slot. The DL2_BIT[7:0] bits have no effect when the DL2_EVEN and DL2_ODD bits of the TXCI Data Link 2 Control register are both logic 0. PROPRIETARY AND CONFIDENTIAL 178 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W DL3_EVEN 0 Bit 6 R/W DL3_ODD 0 Unused X 07 20 t, R/W DL3_TS[4] 0 Bit 3 R/W DL3_TS[3] 0 Bit 2 R/W DL3_TS[2] Bit 1 R/W DL3_TS[1] Bit 0 R/W DL3_TS[0] ug us Bit 4 2A Bit 5 :2 Type 01 Bit 6: Register 03CH: TXCI Transmit Data Link 3 Control 0 sd ay ,0 0 0 o on Th ur This register, along with the TXCI Data Link 3 Bit Select register, controls the insertion of the data link generated by TDPR #3. Refer to the "Using the Internal HDLC Transmitters" description in the Operation section for details on terminating HDLC frames. cir DL3_EVEN: ab do u DL3_ODD: ra s ha d of bn ha The data link 3 even select (DL3_EVEN) bit controls whether or not the third data link is inserted into the even frames of the receive data stream. If DL3_EVEN is a logic 0, the data link is not inserted into the even frames. If DL3_EVEN is a logic 1, the data link is inserted into the even frames. In E1 mode, the frames in an E1 CRC-4 multiframe are considered to be numbered from 0 to 15; in T1 mode, the frames in a superframe are considered to be numbered from 1 to 12 (or 1 to 24 in an extended superframe). ed by The data link 3 odd select (DL3_ODD) bit controls whether or not the third data link is inserted into the odd frames of the receive data stream. If DL3_ODD is a logic 0, the data link is not inserted into the odd frames. If DL3_ODD is a logic 1, the data link is inserted into the odd frames. Do wn l oa d DL3_TS[4:0]: The data link 3 time slot (DL3_TS[4:0]) bits gives a binary representation of the time slot/channel into which the data link is to be inserted. Note that T1 channels 1 to 24 are mapped to values 0 to 23. The DL3_TS[4:0] bits have no effect when DL3_EVEN and DL3_ODD are both a logic 0. PROPRIETARY AND CONFIDENTIAL 179 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DL3_BIT[7] 0 Bit 6 R/W DL3_BIT[6] 0 Bit 5 R/W DL3_BIT[5] 0 Bit 4 R/W DL3_BIT[4] 0 Bit 3 R/W DL3_BIT[3] 0 Bit 2 R/W DL3_BIT[2] Bit 1 R/W DL3_BIT[1] Bit 0 R/W DL3_BIT[0] 01 07 20 t, us ug 0 sd ay ,0 0 0 Th ur DL3_BIT[7:0]: :2 Bit 2A 6: Register 03DH: TXCI Transmit Data Link 3 Bit Select Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The data link 3 bit select (DL3_BIT[7:0]) bits controls into which bits of the time slot/channel data from TDPR #3 are to be inserted. If DL3_BIT[x] is a logic 1, the data link is inserted into that bit. To insert the data link into the entire time slot, all eight DL3_BIT[x] bits must be set to a logic 1. DL3_BIT[7] corresponds to the most significant bit (bit 1, the first bit transmitted) of the time slot and DL3_BIT[0] corresponds to the least significant bit (bit 8, the last bit transmitted) of the time slot. The DL3_BIT[7:0] bits have no effect when the DL3_EVEN and DL3_ODD bits of the TXCI Data Link 3 Control register are both logic 0. PROPRIETARY AND CONFIDENTIAL 180 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W NXDS0[1] 0 Bit 6 R/W NXDS0[0] 0 Bit 5 R/W CMODE 1 Bit 4 R/W DE 1 Bit 3 R/W FE 1 Bit 2 R/W CMS Bit 1 R/W RATE[1] Bit 0 R/W RATE[0] :2 Type 2A ug us t, 20 07 01 Bit 6: Register 040H: BTIF Configuration 0 ,0 ay sd 0 Th ur NXDS0[1:0]: 0 ha - Transmit Backplane NXDS0 Mode Selection bn Table 27 cir o on The NXDS0[1:0] bits determine the mode of operation when BTCLK clock master mode is selected (CMODE logic 0), as shown in the following table. Note that these bits are ignored when clock slave mode is selected (CMODE logic 1). NXDS0[0] 0 0 Full Frame 1 56 kbit/s NxDS0 d of NXDS0[1] ab do u 1 ra s 1 ha 0 Operation 0 64 kbit/s NxDS0 1 64 kbit/s NxDS0 with F-bit (only valid for E1 mode) by When in Full Frame mode, the entire frame (193 bits for T1 or 256 bits for E1) is sampled from the backplane. Do wn l oa d ed When in any of the NxDS0 modes, only those time slots with their IDLE_DS0 bit cleared (logic 0) are sampled from the backplane. The other time slots, with their IDLE_DS0 bit set (logic 1), do not contain valid data and will be overwritten with the per-DS0 idle code. The IDLE_DS0 bits are located in the TPSC Indirect registers. When in T1 mode, the clock is always gapped during the framing bit position. PROPRIETARY AND CONFIDENTIAL 181 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 6: 50 When the 56 kbit/s NxDS0 mode is selected, only the first 7 bits of the selected time slots are sampled from the backplane and the 8th bit is gapped out. When the 64 kbit/s NxDS0 mode is selected, all 8 bits of the selected time slots are sampled from the backplane. ,0 2A ug us t, 20 07 The 64 kbit/s NxDS0 with F-bit mode is intended to support ITU recommendation G.802. This mode is only valid when the E1/T1B register bit is a logic 1 (E1 mode is selected). The operation is the same as the 64 kbit/s NxDS0 mode, except that the framing bit is sampled. The F-bit is always sampled during the first bit of time slot 26. The remaining seven bits of time slot 26 are not sampled. To properly insert a G.802 formatted T1, the IDLE_DS0 bits must be set to logic 0 for time slots 1 through 15 and 17 through 26, and the IDLE_DS0 bits must be set to logic 1 for time slots 27 through 31. ay CMODE: ha cir o on Th ur sd The clock mode (CMODE) bit determines whether the BTCLK pin is an input or output. When CMODE is a logic 0, clock master mode is selected and the BTCLK output is derived from the integral clock synthesizer. Depending on the mode of operation, BTCLK may have a burst frequency of up to 2.048 MHz and may be gapped to support sub-rate applications. In T1 mode, CMODE can only be logic 0 if the backplane rate is 1.544 Mbit/s (RATE[1:0]=00) and CMS=0. In E1 mode, CMODE can only be logic 0 if the backplane rate is 2.048 Mbit/s (RATE[1:0]=01) and CMS=0. of bn When CMODE is a logic 1, clock slave mode is selected and BTCLK is an input. d DE: ab do u ra s ha The data edge (DE) bit determines the edge of BTCLK on which BTPCM and BTSIG are sampled. If DE is a logic 0, BTPCM and BTSIG are sampled on the falling edge of BTCLK. If DE is a logic 1, BTPCM and BTSIG are sampled on the rising edge of BTCLK. FE: Do wn l oa d ed by The framing edge (FE) bit determines the edge of BTCLK on which the frame pulse (BTFP) pulse is sampled or updated. If FE is a logic 0, BTFP is sampled or updated on the falling edge of BTCLK. If FE is a logic 1, BTFP is sampled or updated on the rising edge of BTCLK. In the case where FE is not equal to DE, BTFP is sampled one clock edge or updated three clock edges before BTPCM and BTSIG are sampled. PROPRIETARY AND CONFIDENTIAL 182 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 CMS: 07 01 :2 6: The clock mode select (CMS) bit determines the BTCLK frequency multiple. If CMS is a logic 0, BTCLK is at the backplane rate. If CMS is a logic 1, BTCLK is at twice the backplane rate. CMS must be programmed to logic 0 when CMODE=0. 20 RATE[1:0]: - Transmit Backplane Rate 2A Table 28 ug us t, The rate select (RATE[1:0]) bits determine the backplane rate according to the following table: RATE[0] Backplane Rate 0 0 1.544 Mbit/s 0 1 2.048 Mbit/s 1 0 4.096 Mbit/s 1 1 8.192 Mbit/s on Th ur sd ay ,0 RATE[1] ha cir o The 4.096 Mbit/s and 8.192 Mbit/s rates are only supported in clock slave mode (CMODE logic 1). Do wn l oa d ed by ab do u ra s ha d of bn The RATE[1:0] bits can only be set once after reset. PROPRIETARY AND CONFIDENTIAL 183 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W MAP 0 Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X 0 Bit 2 R/W ESF_EN Bit 1 R/W FPTYP Bit 0 R/W FPMODE 07 20 t, us FPINV ug R/W 2A Bit 3 :2 Type 01 Bit 6: Register 041H: BTIF Frame Pulse Configuration 0 sd 1 Th ur MAP: ay ,0 0 cir o on The MAP bit determines the mapping of a 2.048 MHz backplane onto a 1.544 MHz line. This bit is ignored when in E1 mode (E1/T1B register bit is logic 1), when the backplane rate is 1.544 Mbit/s (RATE[1:0] = 'b00), or when in clock master mode (CMODE = 'b0). of bn ha When MAP is a logic 0, every fourth time slot is unused, starting with time slot 0. The framing bit is sampled during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. ab do u FPINV: ra s ha d When MAP is a logic 1, the first 24 time slots (0 to 23) are sampled. The framing bit is sampled during bit 7 of time slot 31 and the rest of the frame (time slots 24 to 30 and bits 0 to 6 of time slot 31) are ignored. ed by The frame pulse inversion (FPINV) bit determines whether BTFP is inverted prior to sampling. If FPINV is a logic 0, BTFP is active high. If FPINV is a logic 1, BTFP is active low. Frame pulse inversion cannot be used when BTFP is configured as an output (FPMODE is a logic 0). Do wn l oa d ESF_EN: The extended superframe enable (ESF_EN) bit determines which superframe alignment is used when in T1 mode and FPTYP is a logic 1. When ESF_EN is a logic 0, superframe alignment is chosen and BTFP pulses (FPMODE logic 0) or is expected (FPMODE logic 1) every 12 frames. When ESF_EN is PROPRIETARY AND CONFIDENTIAL 184 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 a logic 1, extended superframe alignment is chosen and pulses (FPMODE logic 0) or is expected (FPMODE logic 1) every 24 frames. 01 :2 This bit is ignored when in E1 mode or in T1 mode when FPTYP is a logic 0. 07 FPTYP: ug us t, 20 The frame pulse type (FPTYP) bit determines the type of frame pulse on BTFP. When FPTYP is a logic 0, basic frame alignment is chosen and frame pulses occur every frame. When FPTYP is a logic 1, multiframe alignment is chosen. ay ,0 2A In T1 mode, with multiframe alignment pulses (FPMODE logic 0) or is expected (FRMODE logic 1) every 12 or 24 frames as determined by the ESF_EN bit. on Th ur sd In E1 mode, with multiframe alignment when FPMODE is a logic 0, as an output BTFP pulses once every 16 frames to indicate both CRC and signaling multiframe alignment. When BTFP is configured as an input, must be brought high to mark bit 1 of frame 1 of every 16 frame signaling multiframe and brought low following bit 1 of frame 1 of every 16 frame CRC multiframe. of bn ha cir o To properly initialize the transmit HDLC controllers in basic frame alignment mode (FPTYP is logic 0), multiframe alignment (FPTYP is logic 1) must be configured for at least one multiframe (i.e., for at least one multiframe period in frame pulse master mode or for at least one input frame pulse in frame pulse slave mode). After this initialization, the FPTYP can be set to any desired value. ha d FPMODE: Do wn l oa d ed by ab do u ra s The frame pulse mode (FPMODE) bit determines whether BTFP is an input or an output. When FPMODE is a logic 0, frame pulse master mode is selected and BTFP is an output. When FPMODE is a logic 1, frame pulse slave mode is selected and BTFP is an input. Frame pulse master mode cannot be used with transmit backplane clock rates greater than 2.048 MHz. PROPRIETARY AND CONFIDENTIAL 185 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W TPTYP 0 Bit 6 R/W TPTYE 0 Bit 5 R TDI X Bit 4 R TSIGI X Bit 3 R/W PTY_EXTD 0 Bit 0 Unused 07 20 t, us ug 2A Unused X ,0 Bit 1 X ay Unused sd Bit 2 :2 Type 01 Bit 6: Register 042H: BTIF Parity Configuration and Status X bn ha cir o on Th ur This register provides control and status reporting of data integrity checking on the transmit backplane interface. A single parity bit in the F-bit position represents parity over the previous frame (including the undefined bit positions). Parity checking and generation is not supported when the NxDS0 mode is active. Parity checking and generation is not supported when mapping a 1.544 Mbit/s signal onto a higher rate backplane in the format where the first 24 time slots are used, i.e., the RATE[1:0] bits in the BTIF Configuration register are not set to "00" and the MAP bit in the BTIF Frame Pulse Configuration register is logic 1. of TPTYP: ab do u ra s ha d The transmit parity type (TPTYP) bit sets even or odd parity in the transmit streams. If TPTYP is a logic 0, the expected parity value in the F-bit position of BTPCM and BTSIG is even, thus it is a one if the number of ones in the previous frame is odd. If TPTYP is a logic 1, the expected parity value in the F-bit position if BTPCM and BTSIG is odd, thus it is a one if the number of ones in the previous frame is even. by TPTYE: Do wn l oa d ed The transmit parity enable (TPTYE) bit enables transmit parity interrupts. When TPTYE is a logic 1, parity errors on the inputs BTPCM and BTSIG are indicated by the TDI and TSIGI bits, respectively, and by the assertion low of the INTB output. When TPTYE is a logic 0, parity errors are indicated by the TDI and TSIGI bits but are not indicated on the INTB output. PROPRIETARY AND CONFIDENTIAL 186 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 TDI: 01 :2 6: The transmit data interrupt (TDI) bit indicates if a parity error has been detected on the BTPCM input. This bit is cleared when this register is read. TSIGI: t, 20 07 The transmit signaling interrupt (TSIGI) bit indicated if a parity error has been detected on the BTSIG input. This bit is cleared when this register is read. us PTY_EXTD: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug The parity extend (PRY_EXTD) bit causes the parity to be calculated over the previous frame plus the previous parity bit, instead of only the previous frame. PROPRIETARY AND CONFIDENTIAL 187 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R/W TSOFF[6] 0 Bit 5 R/W TSOFF[5] 0 Bit 4 R/W TSOFF[4] 0 Bit 3 R/W TSOFF[3] 0 Bit 2 R/W TSOFF[2] Bit 1 R/W TSOFF[1] Bit 0 R/W TSOFF[0] t, us ug 0 sd ay ,0 0 0 Th ur TSOFF[6:0]: 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 043H: BTIF Time Slot Offset Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The time slot offset (TSOFF[6:0]) bits give a binary representation of the fixed byte offset between the backplane transmit frame pulse (BTFP) and the start of the next frame on the backplane transmit data signal (BTPCM). The seven bits can give an offset from 0 - 127 bytes. With a data rate of 2.048 Mbit/s, every byte on BTPCM is sampled. With a data rate of 4.096 Mbit/s, every second byte on BTPCM is sampled. With a data rate of 8.192 Mbit/s, every fourth byte on BTPCM is sampled. PROPRIETARY AND CONFIDENTIAL 188 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X 0 R/W BOFF[2] Bit 1 R/W BOFF[1] Bit 0 R/W BOFF[0] 07 20 t, 0 0 0 Th ur BOFF_EN: us Bit 2 ug BOFF_EN 2A R/W ,0 Bit 3 :2 Default 01 Function ay Type sd Bit 6: Register 044H: BTIF Bit Offset ha cir o on The bit offset enable (BOFF_EN) bit is used to enable the bit offset bits. If BOFF_EN is a logic 0, the bit offset is disabled and there is no bit offset between the frame pulse and the first bit of the first time slot. In this case, the BOFF[2:0] bits are ignored. If BOFF_EN is a logic 1, the bit offset is enabled and the BOFF[2:0] bits operate as described below. bn BOFF[2:0]: Do wn l oa d ed by ab do u ra s ha d of The bit offset (BOFF[2:0]) bits gives a binary representation of the fixed offset between the backplane transmit frame pulse (BTFP) and the start of the first bit of the first time slot. This binary representation is then used to determine the BTCLK edge, defined as CER (clock edge receive) on which the first bit of the first time slot is sampled. For example, if CER is 4, the data on BTPCM and BTSIG is sampled on the fourth clock edge after BTFP is sampled (see Figure 11). The following tables show the relationship between BOFF[2:0], FE, DE and CER. PROPRIETARY AND CONFIDENTIAL 189 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 6: BOFF[2:0] :2 DE 000 001 010 011 100 101 110 111 0 4 6 8 10 12 14 16 18 0 1 3 5 7 9 11 13 15 17 1 0 3 5 7 9 11 13 15 17 1 1 4 6 8 10 12 14 16 18 t, us ug 2A CER ,0 - Transmit Backplane Bit Offset for CMS = 1 BOFF[2:0] ay DE 001 010 011 100 101 110 111 18 22 26 30 34 19 23 27 31 35 ur 000 sd Table 30 FE 20 0 07 FE - Transmit Backplane Bit Offset for CMS = 0 01 Table 29 50 AM PMC-1970624 0 6 10 14 0 1 7 11 15 1 0 7 11 15 19 23 27 31 35 1 1 6 10 14 18 22 26 30 34 ha cir o on Th 0 Do wn l oa d ed by ab do u ra s ha d of bn The above tables are consistent with the convention established by the Concentration Highway Interface (CHI) specification. PROPRIETARY AND CONFIDENTIAL 190 CER PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W M2O[1] 0 Bit 6 R/W M2O[0] 0 Bit 5 R/W ESFFA 0 Bit 4 R/W ESF 0 Bit 3 R/W FMS1 0 Bit 2 R/W FMS0 Bit 1 R/W JPN 01 07 20 t, us ug 0 ay ,0 0 Unused sd Bit 0 :2 Bit 2A 6: Register 048H: T1 FRMR Configuration X on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1 or the UNF bit of the Receive Options register is a logic 1, this register is held reset. cir o This register selects the framing format and the frame loss criteria used by the T1-FRMR. ha M2O[1:0]: ab do u ESFFA: ra s ha d of bn The M2O[1:0] bits select the ratio of errored to total framing bits before declaring out of frame in SF, SLC(R)96, and ESF framing formats. A logic 00 selects 2 of 4 framing bits in error; a logic 01 selects 2 of 5 bits in error; a logic 10 selects 2 of 6 bits in error. In T1DM framing format, the ratio of errored to total framing bits before declaring out of frame is always 4 out of 12. A logic 11 in the M2O[1:0] bits is reserved and should not be used. Do wn l oa d ed by The ESFFA bit selects one of two framing algorithms for ESF frame search in the presence of mimic framing patterns in the incoming data. A logic 0 selects the ESF algorithm where the FRMR does not declare inframe while more than one framing bit candidate is following the framing pattern in the incoming data. A logic 1 selects the ESF algorithm where a CRC-6 calculation is performed on each framing bit candidate, and is compared against the CRC bits associated with the framing bit candidate to determine the most likely framing bit position. PROPRIETARY AND CONFIDENTIAL 191 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 ESF: 07 01 :2 6: The ESF bit selects either extended superframe format or enables the Frame Mode Select bits to select either standard superframe, T1DM, or SLC(R)96 framing formats. A logic 1 in the ESF bit position selects ESF; a logic 0 bit enables FMS1 and FMS0 to select SF, T1DM, or SLC(R)96. 20 FMS1,FMS0: ur sd ay ,0 2A ug us t, The FMS1 and FMS0 bits select standard superframe, T1DM, or SLC(R)96 framing formats. A logic 00 in these bits enable the SF framing format; a logic 01 or 11 in these bit positions enable the T1DM framing format; a logic 10 in these bit positions enable the SLC(R)96 framing format. When ESF is selected (ESF bit set to logic 1), the FMS1 and FMS0 bits select the data rate and the source channel for the facility data link data. A logic 00 in these bits enable the FRMR to receive FDL data at the full 4 kHz rate from every odd frame. When ESF is selected, FMS1 and FMS0 settings other than logic 00 are reserved and should not be used. o - T1 Framing Modes FMS1 FMS0 0 0 0 0 0 1 0 1 0 0 1 1 1 0 1 bn of d ha ra s Select T1DM framing format Select SLC96 framing format Select T1DM framing format Select ESF framing format & 4 kHz FDL Data Rate 0 1 Reserved 1 0 Reserved 1 1 Reserved ab do u 1 Select SF framing format 0 by 1 Mode ha ESF cir Table 31 on Th The valid combinations of the ESF, FMS1, and FMS0 bits are summarized in the table below: ed JPN: Do wn l oa d The JPN bit enables Japanese variations of the standard framing formats. If the JPN bit is a logic 1 and the ESF format is selected (ESF bit is logic 1), the T1-FRMR complies to TTC JT-G704. If the JPN bit is a logic 1 and a nonESF format is selected (ESF bit is logic 0), it is assumed the 12th F-bit of the superframe carries a far end receive failure alarm. The alarm is extracted and the framing is modified to be robust when the alarm is active. PROPRIETARY AND CONFIDENTIAL 192 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R/W Reserved 0 Bit 5 R/W COFAE 0 Bit 4 R/W FERE 0 Bit 3 R/W BEEE 0 Bit 2 R/W SFEE Bit 1 R/W MFPE Bit 0 R/W INFRE ug us t, 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 049H: T1 FRMR Interrupt Enable 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1 or the UNF bit of the Receive Options register is a logic 1, this register is held reset. ha cir o This register selects which of the MFP, COFA, FER, BEE, SFE or INFR events generates an interrupt on the microprocessor INTB pin when their state changes or their event condition is detected. bn Reserved: d of The Reserved bit is used for production test purposes only. The Reserved bit must be programmed to logic 0 for normal operation. ha COFAE: by ab do u ra s The COFAE bit enables the generation of an interrupt when the frame find circuitry determines that frame alignment has been achieved and that the new alignment differs from the previous alignment. When COFAE is set to logic 1, the declaration of a change of frame alignment is allowed to generate an interrupt. When COFAE is set to logic 0, a change in the frame alignment does not generate an interrupt on the INTB pin. ed FERE: Do wn l oa d The FERE bit enables the generation of an interrupt when a framing bit error has been detected. When FERE is set to logic 1, the detection of a framing bit error is allowed to generate an interrupt. When FERE is set to logic 0, any error in the framing bits does not generate an interrupt on the INTB pin. PROPRIETARY AND CONFIDENTIAL 193 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 BEEE: us t, 20 07 01 :2 6: The BEEE bit enables the generation of an interrupt when a bit error event has been detected. A bit error event is defined as framing bit errors for SF formatted data, CRC-6 mismatch errors for ESF formatted data, Ft bit errors for SLC(R)96 formatted data, and either framing bit errors or sync word errors for T1DM formatted data. When BEEE is set to logic 1, the detection of a bit error event is allowed to generate an interrupt. When BEEE is set to logic 0, bit error events are disabled from generating an interrupt on the INTB pin. ug SFEE: Th ur sd ay ,0 2A The SFEE bit enables the generation of an interrupt when a severely errored framing event has been detected. A severely errored framing event is defined as 2 or more framing bit errors during the current superframe for SF, ESF, or SLC(R)96 formatted data, and 2 or more framing bit errors or sync word errors during the current superframe for T1DM formatted data. When SFEE is set to logic 1, the detection of a severely errored framing event is allowed to generate an interrupt. When SFEE is set to logic 0, severely errored framing events are disabled from generating an interrupt on the INTB pin. on MFPE: ra s INFRE: ha d of bn ha cir o The MFPE bit enables the generation of an interrupt when the frame find circuitry detects the presence of framing bit mimics. The occurrence of a mimic is defined as more than one framing bit candidate following the frame alignment pattern. When MFPE is set to logic 1, the assertion or deassertion of the detection of a mimic is allowed to generate an interrupt. When MFPE is set to logic 0, the detection of a mimic framing pattern is disabled from generating an interrupt on the INTB pin. ed by ab do u The INFRE bit enables the generation of an interrupt when the frame find circuitry determines that frame alignment has been achieved and that the framer is now "inframe". When INFRE is set to logic 1, the assertion or deassertion of the "inframe" state is allowed to generate an interrupt. When INFRE is set to logic 0, a change in the "inframe" state is disabled from generating an interrupt on the INTB pin. Do wn l oa d Upon reset of the COMET, these bits are set to logic 0, disabling the generation of interrupts on the INTB pin. PROPRIETARY AND CONFIDENTIAL 194 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R COFAI 0 Bit 6 R FERI 0 Bit 5 R BEEI 0 Bit 4 R SFEI 0 Bit 3 R MFPI 0 Bit 2 R INFRI Bit 1 R MFP 2A Bit 0 R INFR ug us t, 20 07 01 :2 Type 0 ay ,0 0 sd Bit 6: Register 04AH: T1 FRMR Interrupt Status 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1 or the UNF bit of the Receive Options register is a logic 1, this register is held reset. ha cir o This register indicate whether a change of frame alignment, a framing bit error, a bit error event, or a severely errored framing event generated an interrupt. This register also indicates whether a mimic framing pattern was detected or whether there was a change in the "inframe" state of the frame circuitry. bn COFAI, FERI, BEEI, SFEI: ab do u MFPI: ra s ha d of A logic 1 in the status bit positions COFAI, FERI, BEEI and SFEI indicate that the occurrence of the corresponding event generated an interrupt; a logic 0 in the status bit positions COFAI, FERI, BEEI, and SFEI indicate that the corresponding event did not generate an interrupt. ed by A logic 1 in the MFPI status bit position indicates that the assertion or deassertion of the mimic detection indication has generated an interrupt; a logic 0 in the MFPI bit position indicates that no change in the state of the mimic detection indication occurred. Do wn l oa d INFRI: A logic 1 in the INFRI status bit position indicates that a change in the "inframe" state of the frame alignment circuitry generated an interrupt; a logic 0 in the INFRI status bit position indicates that no state change occurred. PROPRIETARY AND CONFIDENTIAL 195 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 MFP, INFR: 01 :2 6: The bit position MFP and INFR indicate the current state of the mimic detection and of the frame alignment circuitry. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 The interrupt and the status bit positions (COFAI, FERI, BEEI, SFEI, MFPI, and INFRI) are cleared to logic 0 when this register is read. PROPRIETARY AND CONFIDENTIAL 196 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W Reserved 0 Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X :2 Type R/W DSEL1 0 Bit 2 R/W DSEL0 Bit 1 R/W ASEL1 Bit 0 R/W ASEL0 ug Bit 3 2A us t, 20 07 01 Bit 6: Register 04CH: IBCD Configuration 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. cir o This register provides the selection of the Activate and De-activate loopback code lengths (from 3 bits to 8 bits) as follows: DSEL0 0 0 0 1 1 0 ab do u ra s ha d DSEL1 1 1 ACTIVATE Code of DEACTIVATE Code ha - Loopback Code Configurations bn Table 32 ASEL1 ASEL0 CODE LENGTH 0 0 5 bits 0 1 6 (or 3*) bits 1 0 7 bits 1 1 8 (or 4*) bits ed by Note: Do wn l oa d 3-bit and 4-bit code sequences can be accommodated by configuring the IBCD for 6 or 8 bits and by programming two repetitions of the code sequence. The Reserved bit is used for production test purposes only. The Reserved bit must be programmed to logic 0 for normal operation. PROPRIETARY AND CONFIDENTIAL 197 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R LBACP 0 Bit 6 R LBDCP 0 Bit 5 R/W LBAE 0 Bit 4 R/W LBDE 0 Bit 3 R LBAI 0 Bit 2 R LBDI Bit 1 R LBA 2A Bit 0 R LBD ug us t, 20 07 01 :2 Type 0 ay ,0 0 sd Bit 6: Register 04DH: IBCD Interrupt Enable/Status 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. LBACP, LBDCP: ha cir o The LBACP and LBDCP bits indicate when the corresponding loopback code is present during a 39.8 ms interval. bn LBAE: LBDE: ab do u ra s ha d of The LBAE bit enables the assertion or deassertion of the inband Loopback Activate (LBA) detect indication to generate an interrupt on the microprocessor INTB pin. When LBAE is set to logic 1, any change in the state of the LBA detect indication generates an interrupt. When LBAE is set to logic 0, no interrupt is generated by changes in the LBA detect state. oa d ed by The LBDE bit enables the assertion or deassertion of the inband Loopback Deactivate (LBD) detect indication to generate an interrupt on the microprocessor INTB pin. When LBDE is set to logic 1, any change in the state of the LBD detect indication generates an interrupt. When LBDE is set to logic 0, no interrupt is generated by changes in the LBD detect state. Do wn l LBAI, LBDI: The LBAI and LBDI bits indicate which of the two expected loopback codes generated the interrupt when their state changed. A logic 1 in these bit positions indicate that a state change in that code has generated an interrupt; a logic 0 in these bit positions indicate that no state change has occurred. PROPRIETARY AND CONFIDENTIAL 198 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 LBA, LBD: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: The LBA and LBD bits indicate the current state of the corresponding loopback code detect indication. A logic 1 in these bit positions indicate the presence of that code has been detected; a logic 0 in these bit positions indicate the absence of that code. PROPRIETARY AND CONFIDENTIAL 199 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W ACT7 0 Bit 6 R/W ACT6 0 Bit 5 R/W ACT5 0 Bit 4 R/W ACT4 0 Bit 3 R/W ACT3 0 Bit 2 R/W ACT2 Bit 1 R/W ACT1 Bit 0 R/W ACT0 ug us t, 20 07 01 :2 Bit 2A 6: Register 04EH: IBCD Activate Code 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. of bn ha cir o This 8-bit register selects the Activate code sequence that is to be detected. If the code sequence length is less than 8 bits, the first 8 bits of several repetitions of the code sequence must be used to fill the 8-bit register. For example, if code sequence is a repeating 00001, the first 8 bits of two repetitions (0000100001) is programmed into the register, i.e.00001000. Note that bit ACT7 corresponds to the first code bit received. Do wn l oa d ed by ab do u ra s ha d Upon reset of the COMET, the register contents are set to logic 0. PROPRIETARY AND CONFIDENTIAL 200 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DACT7 0 Bit 6 R/W DACT6 0 Bit 5 R/W DACT5 0 Bit 4 R/W DACT4 0 Bit 3 R/W DACT3 0 Bit 2 R/W DACT2 Bit 1 R/W DACT1 Bit 0 R/W DACT0 ug us t, 20 07 01 :2 Bit 2A 6: Register 04FH: IBCD Deactivate Code 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. of bn ha cir o This 8-bit register selects the Deactivate code sequence that is to be detected. If the code sequence length is less than 8 bits, the first 8 bits of several repetitions of the code sequence must be used to fill the 8-bit register. For example, if code sequence is a repeating 001, the first 8 bits of three repetitions (001001001) is programmed into the register, i.e.00100100. Note that bit DACT7 corresponds to the first code bit received. Do wn l oa d ed by ab do u ra s ha d Upon reset of the COMET, the register contents are set to logic 0. PROPRIETARY AND CONFIDENTIAL 201 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W Reserved 0 Bit 6 R/W COSS 0 Bit 5 R/W SIGE 0 Bit 4 R/W Reserved 0 Bit 3 R/W Reserved 0 Bit 2 R/W ESF Bit 1 R/W IND Bit 0 R/W PCCE :2 Type 2A ug us t, 20 07 01 Bit 6: Register 050H: SIGX Configuration Register (COSS = 0) 0 sd ay ,0 0 Th ur Reserved: 0 on These bits must be a logic 0 for correct operation. o COSS: ha d of bn ha cir The COSS bit allows the channels to be polled to determine in which channel(s) the signaling state has changed. When COSS is a logic 1, the SIGX register space is configured to allow the change of signaling state event bits to be read. When COSS is a logic 0, the SIGX register space is configured to allow indirect access to the configuration and signaling data for each of the 24 T1 or 30 E1 channels. ra s SIGE: ab do u The SIGE bit enables a change of signaling state in any one of the 24 channels (T1 mode) or 30 channels for (E1 mode ) to generate an interrupt on the INTB output. by When SIGE is set to logic 1, a change of signaling state in any channel generates an interrupt. When SIGE is set to logic 0, the interrupt is disabled. The framing format in T1 mode is controlled by the ESF bit. A logic 1 in the ESF bit position selects ESF; a logic 0 bit selects SF, SLC(R)96 or T1DM. When in E1 mode, this bit is ignored. Do wn l oa d ed ESF: PROPRIETARY AND CONFIDENTIAL 202 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 IND: 01 :2 6: The IND bit controls the microprocessor access type: either indirect or direct. IND must be logic 1 for proper operation. PCCE: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 The per-timeslot/per-channel configuration enable bit, PCCE, enables the configuration data in the per-timeslot/per-channel registers to affect the BRSIG and BRPCM data streams. A logic 1 in the PCCE bit position enables the Per-Timeslot/Per-Channel Configuration Register bits in the indirect registers 40H through 5FH; a logic 0 disables the Per-Timeslot/Per-Channel Configuration Register bits in those registers. Please refer to the Per-timeslot/Per-Channel Configuration descriptions for configuration bit details. When the TSB is reset, the PCCE bit is set to logic 0, disabling the Per-Timeslot/Per-Channel Configuration Register bits. PROPRIETARY AND CONFIDENTIAL 203 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R/W COSS 0 Bit 5 R COSS[30] X Bit 4 R COSS[29] X Bit 3 R COSS[28] X Bit 2 R COSS[27] Bit 1 R COSS[26] Bit 0 R COSS[25] t, us ug X sd ay ,0 X X Th ur COSS[30:25]: 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 050H: SIGX Change of Signaling State Register (COSS = 1) d of bn ha cir o on The COSS[30:25] bits will be set to logic 1 if a change of signaling state occurs on the corresponding E1 timeslot. COSS[30:25] are cleared after this register is read. COSS[30:25] are valid only if the E1/T1B register bit is a logic 1. The COSS bit allows the timeslot to be polled to determine in which timeslot(s) the signaling state has changed. When COSS is a logic 1, the SIGX register space is configured to allow the change of signaling state event bits to be read. When COSS is a logic 0, the SIGX register space is configured to allow indirect access to the configuration and signaling data for each of the 24 T1 or 30 E1 channels. Do wn l oa d ed by ab do u ra s ha COSS[25] through COSS[30] correspond to timeslots 26 through 31. PROPRIETARY AND CONFIDENTIAL 204 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default R BUSY 0 Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 Unused 01 07 20 t, us ug X ,0 X ay Bit 7 :2 Type sd Bit 6: Register 051H: SIGX Timeslot Indirect Status (COSS = 0) X Th ur The Timeslot Indirect Status Register is provided at SIGX read/write address 1. on BUSY: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o The BUSY bit is set to logic 1 while the timeslot data is being retrieved or while the configuration data is being written. The bit is set to logic 0 when the read or write cycle has been completed. The BUSY signal holds off a microprocessor read or write access until the SIGX has completed the previous request. This register should be polled until the BUSY bit is logic 0. The bits in this register are valid only when COSS = 0. PROPRIETARY AND CONFIDENTIAL 205 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R COSS[24] X Bit 6 R COSS[23] X Bit 5 R COSS[22] X Bit 4 R COSS[21] X Bit 3 R COSS[20] X Bit 2 R COSS[19] Bit 1 R COSS[18] 2A Bit 0 R COSS[17] 01 07 20 t, us ug X ay ,0 X X Th ur COSS[24:17]: :2 Type sd Bit 6: Register 051H: SIGX Change Of Signaling State Change (COSS=1) cir o on The COSS[24:17] bits will be set to logic 1 if a change of signaling state occurs on the corresponding E1 timeslot OR T1 channel. COSS[24:17] are cleared after this register is read. bn ha In E1 mode, COSS[17] through COSS[24] correspond to timeslots 18 through 25. Do wn l oa d ed by ab do u ra s ha d of For the purposes of signaling extraction, the T1 channels are indexed 1 through 24. PROPRIETARY AND CONFIDENTIAL 206 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W RWB 0 Bit 6 R/W A[6] 0 Bit 5 R/W A[5] 0 Bit 4 R/W A[4] 0 Bit 3 R/W A[3] 0 Bit 2 R/W A[2] Bit 1 R/W A[1] Bit 0 R/W A[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 052H: SIGX Timeslot Indirect Address/Control (COSS = 0) 0 sd ay ,0 0 0 on Th ur If the SIGX is enabled for direct microprocessor access, writing to and reading from the Timeslot Indirect Address Register will not generate any additional accesses. cir o A[6:0]: of bn ha If the SIGX is enabled for indirect microprocessor access, writing to the Timeslot Indirect Address Register initiates a microprocessor access request to one of the registers in segments 2 and 3. The desired register is addressed using the value written to bits A[6:0]. ha d RWB: oa d ed by ab do u ra s The RWB bit indicates which operation is requested. If RWB is set to logic 1, a read is requested. After the request has been issued, the Timeslot Indirect Status register should be monitored to verify completion of the read. The desired register contents can then be found in the Timeslot Indirect Data Register. If RWB is set to logic 0, a write is requested. Data to be written to the microprocessor should first be placed in the Timeslot Indirect Data Register. For both read and write operations, the BUSY bit in the Timeslot Indirect Status Register should be monitored to ensure that the previous access has been completed. Do wn l Note: If the value written to A[6:0] addresses a segment 1 register, an access is not initiated. PROPRIETARY AND CONFIDENTIAL 207 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R COSS[16] X Bit 6 R COSS[15] X Bit 5 R COSS[14] X Bit 4 R COSS[13] X Bit 3 R COSS[12] X Bit 2 R COSS[11] Bit 1 R COSS[10] 2A Bit 0 R COSS[9] 01 07 20 t, us ug X ay ,0 X X Th ur COSS[16:9]: :2 Type sd Bit 6: Register 052H: SIGX Change of Signaling State Register (COSS = 1) cir o on The COSS[16:9] bits will be set to logic 1 if a change of signaling state occurs on the corresponding E1 timeslot or T1 channel. COSS[16:9] are cleared after this register is read. bn ha In E1 mode, COSS[9] through COSS[15] correspond to timeslots 9 through 15 and COSS[16] corresponds to timeslot 17. Do wn l oa d ed by ab do u ra s ha d of For the purposes of signaling extraction, the T1 channels are indexed 1 through 24. PROPRIETARY AND CONFIDENTIAL 208 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W D[7] X Bit 6 R/W D[6] X Bit 5 R/W D[5] X Bit 4 R/W D[4] X Bit 3 R/W D[3] X Bit 2 R/W D[2] Bit 1 R/W D[1] Bit 0 R/W D[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 053H: SIGX Timeslot Indirect Data Buffer (COSS = 0) X sd ay ,0 X X Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur In the case of an indirect write, the Indirect Data Register holds the value that will be written to the desired register when a write is initiated via the Timeslot Indirect Address Register. In the case of an indirect read, the Indirect Data Register will hold the contents of the indirectly addressed register, when the read has been completed. Please refer below to the per-timeslot register descriptions for the expected bit formats. PROPRIETARY AND CONFIDENTIAL 209 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R COSS[8] X Bit 6 R COSS[7] X Bit 5 R COSS[6] X Bit 4 R COSS[5] X Bit 3 R COSS[4] X Bit 2 R COSS[3] Bit 1 R COSS[2] 2A Bit 0 R COSS[1] 01 07 20 t, us ug X ay ,0 X X Th ur COSS[8:1]: :2 Type sd Bit 6: Register 053H: SIGX Change of Signaling State (COSS = 1) cir o on The COSS[8:1] bits will be set to logic 1 if a change of signaling state occurs on the corresponding E1 timeslot or T1 channel. COSS[8:1] are cleared after this register is read. ha In E1 mode, COSS[1] through COSS[8] correspond to timeslots 1 through 8. of bn For the purposes of signaling extraction, the T1 channels are indexed 1 through 24. ha d SIGX Indirect Registers ab do u ra s The signaling and per-timeslot functions are allocated within the indirect registers as follows: Table 33 - SIGX Indirect Register Map Do wn l oa d ed by Addr Register 10H Current Signaling Data Register for Ch 1 and 17 11H Current Signaling Data Register for TS1 and 17/Ch 2 and 18 12H Current Signaling Data Register for TS2 and 18/Ch 3 and 19 13H Current Signaling Data Register for TS3 and 19/Ch 4 and 20 14H Current Signaling Data Register for TS4 and 20/Ch 5 and 21 15H Current Signaling Data Register for TS5 and 21/Ch 6 and 22 PROPRIETARY AND CONFIDENTIAL 210 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Register 16H Current Signaling Data Register for TS6 and 22/Ch 7 and 23 17H Current Signaling Data Register for TS7 and 23/Ch 8 and 24 18H Current Signaling Data Register for TS8 and 24/Ch 9 19H Current Signaling Data Register for TS9 and 25/Ch 10 1AH Current Signaling Data Register for TS10 and 26/Ch 11 1BH Current Signaling Data Register for TS11 and 27/Ch 12 1CH Current Signaling Data Register for TS12 and 28/Ch 13 1DH Current Signaling Data Register for TS13 and 29/Ch 14 1EH Current Signaling Data Register for TS14 and 30/Ch 15 1FH Current Signaling Data Register for TS15 and 31/Ch 16 20H Delayed Signaling Data Register for Ch 1 21H Delayed Signaling Data Register for TS1/Ch 2 22H Delayed Signaling Data Register for TS2/Ch 3 * * 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha d 30H Delayed Signaling Data Register for TS17/Ch 18 ab do u * * * 37H Delayed Signaling Data Register for TS23/Ch 24 by * 38H Delayed Signaling Data Register for TS24 * * * * * * 3EH Delayed Signaling Data Register for TS30 3FH Delayed Signaling Data Register for TS31 ed oa d Delayed Signaling Data Register for Ch 17 ra s ha 31H wn l * Delayed Signaling Data Register for TS15/Ch 16 of 2FH * * bn * * 50 Addr * Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PROPRIETARY AND CONFIDENTIAL 211 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 Register 40H TS0/Ch 1 Configuration Data 41H TS1/Ch 2 Configuration Data * * * * * * 57H TS23/Ch 24 Configuration Data 58H TS24 Configuration Data * ug us t, 20 07 01 :2 6: 50 Addr 2A PMC-1970624 ,0 * * ay * * sd * TS 30 Configuration Data 5FH TS 31 Configuration Data on Th ur 5EH Function Default A TS/Ch `n' X B TS/Ch `n' X C TS/Ch `n' X ha Type R Bit 6 R Bit 5 R Bit 4 R D TS/Ch `n' X R A TS/Ch `n+16' X R B TS/Ch `n+16' X R C TS/Ch `n+16' X R D TS/Ch `n+16' X Bit 1 of ed by Bit 0 d ha ra s Bit 3 Bit 2 bn Bit 7 ab do u Bit cir o Table 34 - SIGX Indirect Registers 10H - 1FH: Current Timeslot/Channel Signaling Data Do wn l oa d Timeslot (E1 mode) and Channel (T1 mode) signaling data can be read from the Timeslot/Channel Signaling Data registers. In E1 mode, TS0 and TS16 do not contain valid data and are not available for reading. The signaling data is termed "Current" here because it is available in the same signaling multi-frame that the COSS[x] indication is available. Note that the signaling data is stored in nibble format. PROPRIETARY AND CONFIDENTIAL 212 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X :2 Bit 7 01 Default us t, 20 07 Function ug Type Bit 3 R A TS/Ch `n' X Bit 2 R B TS/Ch `n' 2A Bit 6: 50 Table 35 - SIGX Indirect Registers 20H - 3FH: Delayed Timeslot/Channel Signaling Data Bit 1 R C TS/Ch `n' Bit 0 R D TS/Ch `n' ,0 X X ur sd ay X Type Function Default Unused X Unused X Unused X Unused X R/W RINV[1] X Bit 2 R/W RINV[0]/RFIX X Bit 1 R/W RPOL X Bit 0 R/W RDEBE X ha d Bit 7 ra s Bit 6 wn l oa d ed by Bit 3 ab do u Bit 5 Bit 4 of Bit - Indirect Registers 40H - 5FH: Per-Timeslot Configuration bn Table 36 ha cir o on Th Timeslot (E1 mode) and Channel (T1 mode) signaling data can be read from the Timeslot/Channel Signaling Data registers. Addresses 20H - 37H are valid in T1 mode. Addresses 20H-3FH correspond to TS 0 - TS31. In E1 mode, TS0 and TS16 do not contain valid data. The signaling data is termed "Delayed" here because it is not available until one full signaling multi-frame after the COSS[x] indication is available. Do RINV[1:0] / RFIX: In T1 mode, the RINV[1] and SIGNINV bit of the RPSC Data Control byte can be used to invert data as shown in Table 37: PROPRIETARY AND CONFIDENTIAL 213 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 - SIGX Per-Channel T1 Data Conditioning 50 Table 37 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 SIGNINV Effect on PCM Channel Data 0 0 PCM Channel data is unchanged 1 0 All 8 bits of the received PCM channel data are inverted 0 1 Only the MSB of the received PCM channel data is inverted (SIGN bit inversion) 1 1 All bits EXCEPT the MSB of the received PCM channel data is inverted (Magnitude inversion) 2A ug us t, 20 07 01 :2 6: RINV[1] ay ,0 In E1 mode, the RINV[1:0] bits select bits within the timeslot are inverted. The bit mapping is as shown in Table 38. - SIGX Per-Channel E1 Data Conditioning sd Table 38 RINV[0] Effect on PCM Channel Data 0 0 do not invert 0 1 invert even bits (2,4,6,8) 1 0 invert odd bits (1,3,5,7) 1 1 invert all bits bn ha cir o on Th ur RINV[1] ha d of Because of the distinct requirements for E1 and T1, the register bits have different definitions in the two modes. In E1 mode bit 2 is defined as RINV[0]; whereas in T1 it is RFIX. RINV[1] has a different effect for the two modes. by ab do u ra s In T1 mode, RFIX controls whether the signaling bit (the least significant bit of the DS0 channel on BRPCM during signaling frames) is fixed to the polarity specified by the RPOL bit. A logic 1 in the RFIX position enables bit fixing; a logic 0 in the RFIX position disables bit fixing. Note that the RPSC functions (inversion, digital milliwatt code insertion, trunk conditioning, and PRBS detection or insertion) take place after bit fixing. Do wn l oa d ed RPOL: In T1 mode, the RPOL bit selects the logic level the signaling bit is fixed to when bit fixing is enabled. When RPOL is a logic 1, the signaling is fixed to logic 1. When RPOL is a logic 0, the signaling is fixed to logic 0. RDEBE: The RDEBE bit enables debouncing of timeslot/channel signaling bits. A logic 1 in this bit position enables signaling debouncing while a logic 0 PROPRIETARY AND CONFIDENTIAL 214 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 disables it. When debouncing is selected, per-timeslot/per-channel signaling transitions are ignored until two consecutive, equal values are sampled. Debouncing is performed on a per signaling bit basis. t, 20 07 01 Data inversion, data trunk conditioning, and digital milliwatt insertion are performed independently of the received framing format. Digital milliwatt insertion takes precedence over data trunk conditioning which, in turn, takes precedence over the various data inversions. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us To enable the RINV[1], RINV[0]/RFIX, RPOL, RDEBE bits, the PCCE bit in the SIGX Configuration Register must be set to logic 1. PROPRIETARY AND CONFIDENTIAL 215 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W MTRK 0 Bit 6 R/W JPN 0 Bit 5 R/W B8ZS 0 Bit 4 R/W ESF 0 Bit 3 R/W FMS1 0 Bit 2 R/W FMS0 Bit 1 R/W ZCS1 Bit 0 R/W ZCS0 ug us t, 20 07 01 :2 Bit 2A 6: Register 054H: T1 XBAS Configuration 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. MTRK: bn ha cir o The MTRK bit forces trunk conditioning, idle code substitution and signaling conditioning, on all channels when MTRK is a logic 1. This has the same effect as setting the IDLE_DS0 bit in the PCM Control byte and the SIG0 bit in the SIGNALING Control byte for all channels. of JPN: by ab do u ra s ha d The JPN bit enables Japanese variations of the standard framing formats. If the JPN bit is a logic 1 and the ESF format is selected (ESF bit is logic 1), the XBAS complies to TTC JT-G704. If the JPN bit is a logic 1 and the SF format is selected, the framing bit of frame 12 is forced to logic 1 when a Yellow alarm is declared. Otherwise, bit 2 in all of the channels is forced to logic 0 to indicate Yellow alarm. Framing insertion must be enabled in order to transmit the alternate SF Yellow alarm. ed B8ZS: oa d The B8ZS bit enables B8ZS line coding when it is a logic 1. When the B8ZS bit is a logic 0, AMI coding is used. Do wn l ESF, FMS1, FMS0: The ESF bit selects either Extended Superframe format or enables the Frame Mode Select bits (FMS) to select either regular superframe, T1DM or SLC(R)96 framing formats. The mode is encoded as follows: PROPRIETARY AND CONFIDENTIAL 216 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 - T1 Framing Formats 50 Table 39 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 FMS1 FMS0 MODE 0 0 0 SF framing format 0 0 1 T1DM framing format (R bit unaffected) 0 1 0 SLC(R)96 0 1 1 T1DM framing format (FDL data replaces R bit) 1 0 0 ESF framing format - 4 kbit/s data link 1 0 1 Reserved 1 1 0 Reserved 1 1 1 Reserved sd ay ,0 2A ug us t, 20 07 01 :2 6: ESF ur ZCS[1:0]: o on Th The ZCS[1:0] bits select the Zero Code Suppression format to be used. These bits are logically ORed with the ZCS[1:0] bits in the TPSC per-channel PCM Control byte. The bits are encoded as follows: - T1 Zero Code Suppression Formats cir Table 40 ZCS0 Zero Code Suppression Format 0 0 None 0 1 GTE Zero Code Suppression (Bit 8 of an all zero channel byte is replaced by a one, except in signaling frames where bit 7 is forced to a one.) 1 0 ab do u ra s ha d of bn ha ZCS1 1 Bell Zero Code Suppression (Bit 7 of an all zero channel byte is replaced by a one.) Do wn l oa d ed by 1 DDS Zero Code Suppression (All zero data byte replaced with "10011000") PROPRIETARY AND CONFIDENTIAL 217 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused 2A R/W XYEL Bit 0 R/W XAIS 01 07 20 t, us ug X 0 ,0 Bit 1 :2 Function ay Type sd Bit 6: Register 055H: T1 XBAS Alarm Transmit 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. o This register controls the transmission of Yellow or AIS alarm. cir XYEL XAIS: ab do u ra s ha d of bn ha The XYEL bit enables the XBAS to generate a Yellow alarm in the appropriate framing format. When XYEL is set to logic 1, XBAS is enabled to set bit 2 of each channel to logic 0 for SF and SLC(R)96 formats, the Y-bit to logic 0 for T1DM format, and XBAS is enabled to transmit repetitions of 1111111100000000 (the Yellow Alarm BOC) on the FDL for ESF format. If the JPN bit of the T1-XBAS Configuration register is a logic 1 and the SF format is selected, the framing bit of frame 12 is forced to logic 1 when a Yellow alarm is enabled. When XYEL is set to logic 0, XBAS is disabled from generating the Yellow alarm. Do wn l oa d ed by The XAIS bit enables the XBAS to generate an unframed all-ones AIS alarm. When XAIS is set to logic 1, the XBAS bipolar outputs are forced to pulse alternately, creating an all-ones signal. When XAIS is set to logic 0, the XBAS bipolar outputs operate normally. PROPRIETARY AND CONFIDENTIAL 218 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W EN 0 Bit 6 R/W UF 0 Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 0 R/W CL0 01 07 20 t, us ug 0 ,0 CL1 ay R/W X sd Bit 1 :2 Bit 2A 6: Register 056H: T1 XIBC Control 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. EN: bn ha cir o The EN bit controls whether the Inband Code is transmitted or not. A logic 1 in the EN bit position enables transmission of inband codes; a logic 0 in the EN bit position disables inband code transmission. of UF: by ab do u ra s ha d The UF bit controls whether the code is transmitted framed or unframed. A logic 1 in the UF bit position selects unframed inband code transmission; a logic 0 in the UF bit position selects framed inband code transmission. Note: the UF register bit controls the XBAS directly and is not qualified by the EN bit. When UF is set to logic 1, the XBAS is disabled and no framing is inserted regardless of the setting of EN. The UF bit should only be written to logic 1 when the EN bit is set, and should be cleared to logic 0 when the EN bit is cleared. ed CL1, CL0: Do wn l oa d The bit positions CL1 and CL0 of this register indicate the length of the inband loopback code sequence, as follows: PROPRIETARY AND CONFIDENTIAL 219 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Code Length 0 0 5 0 1 6 1 0 7 1 1 8 6: CL0 us t, 20 07 01 CL1 50 - Transmit In-band Code Length :2 Table 41 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug Codes of 3 or 4 bits in length may be accommodated by treating them as half of a double-sized code (i.e., a 3-bit code would use the 6-bit code length setting). PROPRIETARY AND CONFIDENTIAL 220 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W IBC7 X Bit 6 R/W IBC6 X Bit 5 R/W IBC5 X Bit 4 R/W IBC4 X Bit 3 R/W IBC3 X Bit 2 R/W IBC2 Bit 1 R/W IBC1 Bit 0 R/W IBC0 ug us t, 20 07 01 :2 Bit 2A 6: Register 057H: T1 XIBC Loopback Code X sd ay ,0 X X on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. of bn ha cir o This register contains the inband loopback code pattern to be transmitted. The code is transmitted most significant bit ( IBC7) first, followed by IBC6 and so on. The code, regardless of the length, must be aligned with the MSB always in the IBC7 position (e.g., a 5-bit code would occupy the IBC7 through IBC2 bit positions). To transmit a 3-bit or a 4-bit code pattern, the pattern must be paired to form a double-sized code (i.e., the 3-bit code '011' would be written as the 6-bit code '011011'). Do wn l oa d ed by ab do u ra s ha d When the COMET is reset, the contents of this register are not affected. PROPRIETARY AND CONFIDENTIAL 221 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X INTE Bit 1 R XFER Bit 0 R OVR 07 20 t, us ug 2A R/W 0 0 ,0 Bit 2 :2 Default 01 Function ay Type sd Bit 6: Register 058H: PMON Interrupt Enable/Status 0 on Th ur This register contains status information indicating when counter data has been transferred into the holding registers and indicating whether the holding registers have been overrun. cir o INTE: d of bn ha The INTE bit controls the generation of a microprocessor interrupt when the transfer clock has caused the counter values to be stored in the holding registers. A logic 1 bit in the INTE position enables the generation of an interrupt via the INTB output; a logic 0 bit in the INTE position disables the generation of an interrupt. ha XFER: by ab do u ra s The XFER bit indicates that a transfer of counter data has occurred. A logic 1 in this bit position indicates that a latch request, initiated by writing to one of the counter register locations or the Global PMON Update register, was received and a transfer of the counter values has occurred. A logic 0 indicates that no transfer has occurred. The XFER bit is cleared (acknowledged) by reading this register. ed OVR: Do wn l oa d The OVR bit is the overrun status of the holding registers. A logic 1 in this bit position indicates that a previous transfer (indicated by XFER being logic 1) has not been acknowledged before the next transfer clock has been issued and that the contents of the holding registers have been overwritten. A logic 0 indicates that no overrun has occurred. The OVR bit is cleared by reading this register. PROPRIETARY AND CONFIDENTIAL 222 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 Registers 059-05FH: Latching Performance Data 2A ug us t, 20 07 01 :2 The Performance Data registers for a single framer are updated as a group by writing to any of the PMON count registers (addresses 059H-05FH). A write to one (and only one) of these locations loads performance data located in the PMON into the internal holding registers. Alternatively, the Performance Data registers are updated by writing to the Revision/Chip ID/Global PMON Update register (address 00DH). The data contained in the holding registers can then be subsequently read by microprocessor accesses into the PMON count register address space. The latching of count data, and subsequent resetting of the counters, is synchronized to the internal event timing so that no events are missed. ur sd ay ,0 The PMON is loaded with new performance data within 3.5 recovered clock periods of the latch performance data register write. With nominal line rates, the PMON registers should not be polled until 2.3 sec have elapsed from the "latch performance data" register write. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th When the COMET is reset, the contents of the PMON count registers are unknown until the first latching of performance data is performed. PROPRIETARY AND CONFIDENTIAL 223 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R FER[6] X Bit 5 R FER[5] X Bit 4 R FER[4] X Bit 3 R FER[3] X Bit 2 R FER[2] Bit 1 R FER[1] Bit 0 R FER[0] ug us t, 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 059H: PMON Framing Bit Error Count X sd ay ,0 X Th ur FER[6:0]: X ha cir o on The FER[6:0] bits indicate the number of framing bit error events that occurred during the previous accumulation interval. The FER counts are suppressed when the framer has lost frame alignment (OOF in the E1-FRMR Framing Status register is logic 1 or INFR in the T1-FRMR Interrupt Status register is logic 0). bn In T1 mode, a framing bit error is defined as an Fe-bit error in ESF, a framing bit error in SF, FT-bit error in SLC(R)96, or an F-bit error in T1DM. Do wn l oa d ed by ab do u ra s ha d of In E1 mode, the count is either the number of FAS (frame alignment signal) bits (default) or words in error. As an option, a zero in bit 2 of time slot 0 of non-frame alignment signal (NFAS) frames results in an increment of the framing error count. Refer to the Receive Options register. PROPRIETARY AND CONFIDENTIAL 224 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R OOF/FEBE[7] X Bit 6 R OOF/FEBE[6] X Bit 5 R OOF/FEBE[5] X Bit 4 R OOF/FEBE[4] X Bit 3 R OOF/FEBE[3] X Bit 2 R OOF/FEBE[2] Bit 1 R OOF/FEBE[1] 2A Bit 0 R OOF/FEBE[0] 225 01 07 20 t, us ,0 ay sd Th on o cir ha bn of d ha ra s ab do u by ed oa d wn l Do PROPRIETARY AND CONFIDENTIAL ug X X X :2 Type ur Bit 6: Register 05AH: PMON OOF/COFA/Far End Block Error Count LSB PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused 2A ug us t, 20 07 01 :2 Function X R OOF/FEBE[9] Bit 0 R OOF/FEBE[8] X Th ur OOF/FEBE[9:0]: X ,0 Bit 1 ay Type sd Bit 6: Register 05BH: PMON OOF/COFA/Far End Block Error Count MSB bn ha cir o on In T1 mode, the OOF[9:0] bits indicate the number Out Of Frame or Change Of Frame Alignment events that occurred during the previous accumulation interval, as specified by the CCOFA bit in the Receive Options register. If OOFs are being accumulated, the count is incremented each time a severely errored framing event forces a reframe. IF COFAs are being accumulated, the count is incremented if a new alignment differs from the previous alignment. Do wn l oa d ed by ab do u ra s ha d of In E1 mode, the FEBE[9:0] bits indicate the number of far end block error events that occurred during the previous accumulation interval. The FEBE counts are suppressed when the E1 FRMR has lost frame alignment (OOF in the FRMR Framing Status register is set). PROPRIETARY AND CONFIDENTIAL 226 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R BEE/CRCE[7] X Bit 6 R BEE/CRCE[6] X Bit 5 R BEE/CRCE[5] X Bit 4 R BEE/CRCE[4] X Bit 3 R BEE/CRCE[3] X Bit 2 R BEE/CRCE[2] Bit 1 R BEE/CRCE[1] 2A Bit 0 R BEE/CRCE[0] 227 01 07 20 t, us ,0 ay sd Th on o cir ha bn of d ha ra s ab do u by ed oa d wn l Do PROPRIETARY AND CONFIDENTIAL ug X X X :2 Type ur Bit 6: Register 05CH: PMON Bit Error/CRC Error Count LSB PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused 2A ug us t, 20 07 01 :2 Function X R BEE/CRCE[9] Bit 0 R BEE/CRCE[8] X Th ur BEE/CRCE[9:0]: X ,0 Bit 1 ay Type sd Bit 6: Register 05DH: PMON Bit Error/CRC Error Count MSB ha cir o on In T1 mode, the BEE[9:0] bits contain the number of bit error events that occurred during the previous accumulation interval. A bit error event is defined as a CRC-6 error in ESF, a framing bit error in SF, an FT-bit error in SLC(R)96, and an F-bit or sync bit error (there can be up to 7 bits in error per frame) in T1DM. Do wn l oa d ed by ab do u ra s ha d of bn In E1 mode, the CRCE[9:0] bits indicate the number of CRC error events that occurred during the previous accumulation interval. CRC error events are suppressed when the E1 FRMR is out of CRC-4 multiframe alignment (OOCMF bit in the FRMR Framing Status register is set). PROPRIETARY AND CONFIDENTIAL 228 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R LCV[7] X Bit 6 R LCV[6] X Bit 5 R LCV[5] X Bit 4 R LCV[4] X Bit 3 R LCV[3] X Bit 2 R LCV[2] Bit 1 R LCV[1] 2A Bit 0 R LCV[0] 01 07 20 t, us ,0 ay sd Th on o cir ha bn of d ha ra s ab do u by ed oa d wn l Do PROPRIETARY AND CONFIDENTIAL ug X X 229 X :2 Type ur Bit 6: Register 05EH: PMON LCV Count (LSB) PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X :2 Default 20 07 01 Function t, Type R LCV[12] X Bit 3 R LCV[11] X Bit 2 R LCV[10] Bit 1 R LCV[9] Bit 0 R LCV[8] ug us Bit 4 2A Bit 6: Register 05FH: PMON LCV Count (MSB) X sd ay ,0 X Th ur LCV[12:0]: X Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The LCV[12:0] bits indicate the number of LCV error events that occurred during the previous accumulation interval. An LCV event is defined as the occurrence of a Bipolar Violation or Excessive Zeros. The counting of Excessive Zeros can be disabled by the BPV bit of the Receive Line Interface Configuration register. PROPRIETARY AND CONFIDENTIAL 230 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X :2 Default 20 07 01 Function t, Type R/W ESF 0 Bit 3 R/W FMS1 0 Bit 2 R/W FMS0 ug us Bit 4 2A Bit 6: Register 060H: T1 ALMI Configuration 0 Unused ,0 Bit 0 X ay Unused sd Bit 1 X on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. cir o This register allows selection of the framing format and the data rate of the Facility Data Link in ESF to allow operation of the CFA detection algorithms. ha ESF: FMS1,FMS0: ra s ha d of bn The ESF bit selects either extended superframe format or enables the frame mode select bits to select either regular superframe, T1DM, "alternate" T1DM, or SLC(R)96 framing formats. A logic 1 in the ESF bit position selects ESF; a logic 0 bit enables FMS1 and FMS0 to select SF, T1DM, "alternate" T1DM, or SLC(R)96. Do wn l oa d ed by ab do u The FMS1 and FMS0 bits select standard superframe, T1DM, "alternate" T1DM, or SLC(R)96 framing formats. A logic 00 in these bits enable the SF framing format; a logic 01 in these bit positions enable the T1DM framing format; a logic 10 in these bit positions enable the SLC(R)96 framing format; and a logic 11 in these bit positions enable the "alternate" T1DM framing format. The "alternate" T1DM framing format configures the ALMI to process the Red alarm as if the SF, SLC(R)96, or ESF framing format were selected; the Yellow alarm is still processed as T1DM. When ESF is selected (ESF bit set to logic 1), the FMS1 and FMS0 bits select the data rate and the source channel for the Facility Data Link (FDL) data. A logic 00 in these bits enables the ALMI to receive FDL data and validate the Yellow alarm at the full 4 kbit rate. PROPRIETARY AND CONFIDENTIAL 231 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 - T1 Framing Modes 01 Table 42 6: 50 The valid combinations of the ESF, FMS1, and FMS0 bits are summarized in the table below: FMS1 FMS0 Mode 0 0 0 Select Superframe framing format 0 0 1 Select T1DM framing format 0 1 0 Select SLC-96 framing format 0 1 1 Select "alternate" T1DM mode 1 0 0 Select ESF framing format & 4 kbit FDL Data Rate 1 0 1 Reserved 1 1 0 Reserved 1 1 1 Reserved Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 ESF PROPRIETARY AND CONFIDENTIAL 232 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X FASTD 0 Bit 3 R/W ACCEL 0 Bit 2 R/W YELE Bit 1 R/W REDE Bit 0 R/W AISE 07 20 t, R/W 2A Bit 4 :2 Default 01 Function us Type ug Bit 6: Register 061H: T1 ALMI Interrupt Enable 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. cir o This register selects which of the three CFA's can generate an interrupt when their logic state changes and enables the "fast" deassertion mode of operation. ha FASTD: ab do u ACCEL: ra s ha d of bn The FASTD bit enables the "fast" deassertion of Red and AIS alarms. When FASTD is set to a logic 1, deassertion of Red alarm occurs within 120 ms of going in frame. Deassertion of AIS alarm occurs within 180 ms of either detecting a 60 ms interval containing 127 or more zeros, or going in frame. When FASTD is set to a logic 0, Red and AIS alarm deassertion times remain as defined in the ALMI description. by The ACCEL bit is used for production test purposes only. THE ACCEL BIT MUST BE PROGRAMMED TO LOGIC 0 FOR NORMAL OPERATION. YELE, REDE, AISE: Do wn l oa d ed A logic 1 in the enable bit positions (YELE, REDE, AISE) enables a state change in the corresponding CFA to generate an interrupt; a logic 0 in the enable bit positions disables any state changes to generate an interrupt. The enable bits are independent; any combination of Yellow, Red, and AIS CFA's can be enabled to generate an interrupt. Upon reset of the COMET, these bits are cleared to logic 0. PROPRIETARY AND CONFIDENTIAL 233 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X :2 Default 07 01 Function 20 Type R YELI 0 Bit 4 R REDI 0 Bit 3 R AISI 0 Bit 2 R YEL Bit 1 R RED Bit 0 R AIS ug us t, Bit 5 2A Bit 6: Register 062H: T1 ALMI Interrupt Status 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o This register indicates which of the three Carry Failure Alarms (CFA's) generated an interrupt when their logic state changed in bit positions 5 through 3, and indicate the current state of each CFA in bit positions 2 through 0. A logic 1 in the status positions (YELI, REDI, AISI) indicate that a state change in the corresponding CFA has generated an interrupt; a logic 0 in the status positions indicates that no state change has occurred. Both the status bit positions (bits 5 through 3) and the interrupt generated because of the change in CFA state are cleared to logic 0 when the register containing then is read. PROPRIETARY AND CONFIDENTIAL 234 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X REDD Bit 1 R YELD Bit 0 R AISD 07 20 t, us ug 2A R X X ,0 Bit 2 :2 Default 01 Function ay Type sd Bit 6: Register 063H: T1 ALMI Alarm Detection Status X on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. ha cir o This register indicates the presence or absence of one or more OOF occurrences within the last 40 ms; the presence or absence of the Yellow alarm signal over the last 40 ms; and indicate the presence or absence of the AIS alarm signal over the last 60 ms. bn REDD: ra s ha d of When REDD is a logic 1, one or more out of frame events have occurred during the last 40 ms interval. When REDD is a logic 0, no out of frame events have occurred within the last 40 ms interval. YELD: bit 2 of each channel is not logic 0 for 16 or fewer times during the 40 ms interval for SF and SLC(R)96 framing formats; the Y-bit is not logic 0 for 4 or fewer times during the 40 ms interval for T1DM framing format; Do wn l oa d ed by ab do u When YELD is logic 1, a valid Yellow signal was present during the last 40 ms interval. When YELD is logic 0, the Yellow signal was absent during the last 40 ms interval. For each framing format, a valid Yellow signal is deemed to be present if: PROPRIETARY AND CONFIDENTIAL 235 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 the 16-bit Yellow bit oriented code is received error-free 8 or more times during the interval for ESF framing format with a 4 kHz data link; 07 01 In a Japanese T1 mode, the 12th F-bit toggles between 1 and 0 signifying a Japanese Yellow alarm 20 AISD: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, When AISD is logic 1, a valid AIS signal was present during the last 60 ms interval. When AISD is logic 0, the AIS signal was absent during the last 60 ms interval. A valid AIS signal is deemed to be present during a 60 ms interval if the out of frame condition has persisted for the entire interval and the received PCM data stream is not logic 0 for 126 or fewer times. PROPRIETARY AND CONFIDENTIAL 236 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X :2 Default 20 07 01 Function t, Type R PDV 0 Bit 3 R Z16DI 0 Bit 2 R PDVI Bit 1 R/W Z16DE Bit 0 R/W PDVE ug us Bit 4 2A Bit 6: Register 065H: T1 PDVD Interrupt Enable/Status 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. Also, this register is only available when the RUNI bit in the Receive Line Interface Configuration register is logic 0. cir o PDV: ra s PDVI, Z16DI: ha d of bn ha The PDV bit indicates the current state of the pulse density violation indication. When PDV is a logic 1, a violation of the pulse density rule exists. When PDV is a logic 0, no violation of the pulse density rule exists. Note: the PDV indication persists for the duration of the pulse density violation. At its minimum, PDV may be asserted for only 1 bit time, therefore, reading this bit may not return a logic 1 even though a pulse density violation has occurred. ed by ab do u The PDVI and Z16DI bits identify the source of a generated interrupt. PDVI is a logic 1 whenever a change in the pulse density violation indication generated an interrupt. PDVI is cleared to 0 when this register is read. Z16DI is a logic 1 whenever 16 consecutive zeros are detected. Z16DI is cleared to 0 when this register is read. Note that the PDVI and Z16DI interrupt indications operate regardless of whether interrupts are enabled or disabled. Do wn l oa d Z16DE: The Z16DE bit enables an interrupt to be generated on the microprocessor INTB pin when 16 consecutive zeros are detected. When Z16DE is set to logic 1, interrupt is generation is enabled. When Z16DE is set to logic 0, interrupt generation is disabled. PROPRIETARY AND CONFIDENTIAL 237 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 PDVE: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: The PDVE bit enables an interrupt to be generated on the microprocessor INTB pin when a change in the pulse density is detected. When PDVE is set to logic 1, an interrupt is generated whenever a pulse density violation occurs or when the pulse density ceases to exist. When PDVE is set to logic 0, interrupt generation by pulse density violations is disabled. PROPRIETARY AND CONFIDENTIAL 238 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X :2 Default 07 01 Function 20 Type R/W BC[5] 1 Bit 4 R/W BC[4] 1 Bit 3 R/W BC[3] 1 Bit 2 R/W BC[2] Bit 1 R/W BC[1] Bit 0 R/W BC[0] ug us t, Bit 5 2A Bit 6: Register 067H: T1 XBOC Code 1 sd ay ,0 1 1 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. cir o This register enables the XBOC to generate a bit oriented code and selects the 6-bit code to be transmitted. Do wn l oa d ed by ab do u ra s ha d of bn ha When this register is written with any 6-bit code other than 111111, that code will be transmitted repeatedly in the ESF Facility Data Link with the format 111111110[BC0][BC1][BC2][BC3][BC4][BC5]0, overwriting any HDLC packets currently being transmitted. When the register is written with 111111, the XBOC is disabled. PROPRIETARY AND CONFIDENTIAL 239 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W STUFE 0 Bit 6 R/W STUFF 0 Bit 5 R STUFI 0 Bit 4 R PDV 0 Bit 3 R Z16DI 0 Bit 2 R PDVI Bit 1 R/W Z16DE Bit 0 R/W PDVE ug us t, 20 07 01 :2 Bit 2A 6: Register 069H: T1 XPDE Interrupt Enable/Status 0 sd ay ,0 0 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. STUFE: bn ha cir o The STUFE bit enables the occurrence of pulse stuffing to generate an interrupt on INTB. When STUFE is set to logic 1, an interrupt is generated on the occurrence of a bit stuff. When STUFE is a logic 0, bit stuffing occurrences do not generate an interrupt on INTB. of STUFF: by ab do u ra s ha d The STUFF bit enables pulse stuffing to occur upon detection of a violation of the pulse density rule. Bit stuffing is performed in such a way that the resulting data stream no longer violates the pulse density rule. When STUFF is set to logic 1, bit stuffing is enabled and the STUFI bit indicates the occurrence of bit stuffs. When STUFF is a logic 0, bit stuffing is disabled and the PDVI bit indicates occurrences of pulse density violation. Also, when STUFF is a logic 0, PCM data passes through XPDE unaltered. ed STUFI: Do wn l oa d The STUFI bit is valid when pulse stuffing is active. This bit indicates when a bit stuff occurred to eliminate a pulse density violation and that an interrupt was generated due to the bit stuff (if STUFE is logic 1). When pulse stuffing is active, PDVI remains logic 0, indicating that the stuffing has removed the density violation. The STUFI bit is reset to logic 0 once this register is read. If the STUFE bit is also logic 1, the interrupt is also cleared once this register is read. PROPRIETARY AND CONFIDENTIAL 240 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 PDV: us t, 20 07 01 :2 6: The PDV bit indicates the current state of the pulse density violation indication. When PDV is a logic 1, a violation of the pulse density rule exists. When PDV is a logic 0, no violation of the pulse density rule exists. Note: the PDV indication persists for the duration of the pulse density violation. At its minimum, PDV may be asserted for only 1 bit time, therefore, reading this bit may not return a logic 1 even though a pulse density violation has occurred. When the XPDE is enabled for pulse stuffing, PDV remains logic 0. ug PDVI, Z16DI: Th ur sd ay ,0 2A The PDVI and Z16DI bits identify the source of a generated interrupt. PDVI is a logic 1 whenever a change in the pulse density violation indication generated an interrupt. PDVI is cleared to 0 when this register is read. Z16DI is a logic 1 whenever 16 consecutive zeros are detected. Z16DI is cleared to 0 when this register is read. Note that the PDVI and Z16DI interrupt indications operate regardless of whether the corresponding interrupt enables are enabled or disabled. When STUFF is set to logic 1, the PDVI and Z16DI bits are forced to logic 0. on Z16DE: bn ha cir o The Z16DE bit enables an interrupt to be generated on the microprocessor INTB pin when 16 consecutive zeros are detected. When Z16DE is set to logic 1, interrupt is generation is enabled. When Z16DE is set to logic 0, interrupt generation is disabled. of PDVE: Do wn l oa d ed by ab do u ra s ha d The PDVE bit enables an interrupt to be generated on the microprocessor INTB pin when a change in the pulse density is detected. When PDVE is set to logic 1, an interrupt is generated whenever a pulse density violation occurs or when the pulse density ceases to exist (if STUFE is logic 0). When PDVE is set to logic 0, interrupt generation by pulse density violations is disabled. PROPRIETARY AND CONFIDENTIAL 241 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X IDLE Bit 1 R/W AVC Bit 0 R/W BOCE 07 20 t, us ug 2A R/W 0 0 ,0 Bit 2 :2 Default 01 Function ay Type sd Bit 6: Register 06AH: T1 RBOC Enable 0 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. ha cir o This register selects the validation criteria to be used in determining a valid bit oriented code (BOC) and enables generation of an interrupt on a change in code status. bn IDLE: ra s ha d of The IDLE bit position enables or disables the generation of an interrupt when there is a transition from a validated BOC to idle code. A logic 1 in this bit position enables generation of an interrupt; a logic 0 in this bit position disables interrupt generation. AVC: by ab do u The AVC bit position selects the validation criteria used in determining a valid BOC. A logic 1 in the AVC bit position selects the "alternate" validation criterion of 4 out of 5 matching BOCs; a logic 0 selects the 8 out of 10 matching BOC criterion. ed BOCE: Do wn l oa d The BOCE bit position enables or disables the generation of an interrupt on the microprocessor INTB pin when a valid BOC is detected. A logic 1 in this bit position enables generation of an interrupt; a logic 0 in this bit position disables interrupt generation. PROPRIETARY AND CONFIDENTIAL 242 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R IDLEI 0 Bit 6 R BOCI 0 Bit 5 R BOC[5] 1 Bit 4 R BOC[4] 1 Bit 3 R BOC[3] 1 Bit 2 R BOC[2] Bit 1 R BOC[1] 2A Bit 0 R BOC[0] ug us t, 20 07 01 :2 Type 1 ay ,0 1 sd Bit 6: Register 06BH: T1 RBOC Code Status 1 on Th ur When the E1/T1B bit of the Global Configuration register is a logic 1, this register is held reset. BOC[5:0]: ha cir o The BOC[5:0] bits indicate the current state value of the received bit-oriented code. bn IDLEI: BOCI: ab do u ra s ha d of The IDLEI bit position indicates whether an interrupt was generated by the detection of the transition from a valid BOC to idle code. A logic 1 in the IDLEI bit position indicates that a transition from a valid BOC to idle code has generated an interrupt; a logic 0 in the IDLEI bit position indicates that no transition from a valid BOC to idle code has been detected. IDLEI is cleared to logic 0 when the register is read. Do wn l oa d ed by The BOCI bit position indicates whether an interrupt was generated by the detection of a valid BOC. A logic 1 in the BOCI bit position indicates that a validated BOC code has generated an interrupt; a logic 0 in the BOCI bit position indicates that no BOC has been detected. BOCI is cleared to logic 0 when the register is read. PROPRIETARY AND CONFIDENTIAL 243 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 R/W Reserved Bit 1 R/W IND Bit 0 R/W PCCE :2 Default us t, 20 07 01 Function ug Type 2A Bit 6: Register 06CH: TPSC Configuration 0 sd ay ,0 0 0 on Th ur This register allows selection of the microprocessor read access type and output enable control for the Transmit Per-channel Serial Controller. Reserved: cir o The Reserved bit must be programmed to logic 0 for normal operation. ha IND: d of bn The IND bit controls the microprocessor access type: either indirect or direct. The IND bit must be set to logic 1 for proper operation. When the COMET is reset, the IND bit is set low, disabling the indirect access mode. ra s ha PCCE: Do wn l oa d ed by ab do u The PCCE bit enables the per-channel functions. When the PCCE bit is set to a logic 1, each channel's PCM Control byte, IDLE Code byte, and SIGNALING Control byte are passed on to the XBAS. When the PCCE bit is set to logic 0, the per-channel functions are disabled. PROPRIETARY AND CONFIDENTIAL 244 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default R BUSY X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 Unused 01 07 20 t, us ug X ,0 X ay Bit 7 :2 Type sd Bit 6: Register 06DH: TPSC P Access Status X Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur The BUSY bit in the Status register is high while a P access request is in progress. The BUSY bit goes low timed to an internal high-speed clock rising edge after the access has been completed. During normal operation, the Status Register should be polled until the BUSY bit goes low before another P access request is initiated. A P access request is typically completed within 640 ns. PROPRIETARY AND CONFIDENTIAL 245 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W R/WB 0 Bit 6 R/W A6 0 Bit 5 R/W A5 0 Bit 4 R/W A4 0 Bit 3 R/W A3 0 Bit 2 R/W A2 Bit 1 R/W A1 Bit 0 R/W A0 ug us t, 20 07 01 :2 Bit 2A 6: Register 06EH: TPSC Channel Indirect Address/Control 0 sd ay ,0 0 0 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur This register allows the P to access the internal TPSC registers addressed by the A[6:0] bits and perform the operation specified by the R/WB bit. Writing to this register with a valid address and R/WB bit initiates an internal P access request cycle. The R/WB bit selects the operation to be performed on the addressed register: when R/WB is set to a logic 1, a read from the internal TPSC register is requested; when R/WB is set to a logic 0, a write to the internal TPSC register is requested. PROPRIETARY AND CONFIDENTIAL 246 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W D7 0 Bit 6 R/W D6 0 Bit 5 R/W D5 0 Bit 4 R/W D4 0 Bit 3 R/W D3 0 Bit 2 R/W D2 Bit 1 R/W D1 Bit 0 R/W D0 ug us t, 20 07 01 :2 Bit 2A 6: Register 06FH: TPSC Channel Indirect Data Buffer 0 ay ,0 0 sd 0 of bn ha cir o on Th ur This register contains either the data to be written into the internal TPSC registers when a write request is initiated or the data read from the internal TPSC registers when a read request has completed. During normal operation, if data is to be written to the internal registers, the byte to be written must be written into this Data register before the target register's address and R/WB=0 is written into the Address/Control register, initiating the access. If data is to be read from the internal registers, only the target register's address and R/WB=1 is written into the Address/Control register, initiating the request. After 640 ns, this register will contain the requested data byte. ab do u ra s ha d The internal TPSC registers control the per-channel functions on the Transmit PCM data, provide the per-channel Transmit IDLE Code, and provide the perchannel Transmit signaling control and the alternate signaling bits. The functions are allocated within the registers as follows: Table 43 Addr by 20H Register PCM Data Control byte for Timeslot 0 PCM Data Control byte for Channel 1/Timeslot 1 22H PCM Data Control byte for Channel 2/Timeslot 2 oa d ed 21H wn l Do - TPSC Indirect Register Map 37H * * * * PCM Data Control byte for Channel 23/Timeslot 23 PROPRIETARY AND CONFIDENTIAL 247 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Register 38H PCM Data Control byte for Channel 24/Timeslot 24 39H PCM Data Control byte for Timeslot 25 * PCM Data Control byte for Timeslot 30 3FH PCM Data Control byte for Timeslot 31 40H IDLE Code byte for Timeslot 0 41H IDLE Code byte for Channel 1/Timeslot 1 42H IDLE Code byte for Channel 2/Timeslot 2 ay ,0 2A ug us t, 3EH sd * ur * * * IDLE Code byte for Channel 23/Timeslot 23 58H IDLE Code byte for Channel 24/Timeslot 24 59H IDLE Code byte for Timeslot 25 cir o on Th 57H * ha * * bn * IDLE Code byte for Timeslot 30 5FH IDLE Code byte for Timeslot 31 60H E1 Control byte for Timeslot 0 61H Signaling/E1 Control byte for Channel 1/Timeslot 1 62H Signaling/E1 Control byte for Channel 2/Timeslot 2 * * Signaling/E1 Control byte for Channel 23/Timeslot 23 78H Signaling/E1 Control byte for Channel 24/Timeslot 24 79H Signaling/E1 Control byte for Timeslot 25 wn l oa d 77H ed by * ab do u ra s ha d of 5EH * Do 01 * 07 * 20 * :2 Addr 50 AM ISSUE 11 6: PMC-1970624 7EH * * * * Signaling/E1 Control byte for Timeslot 30 PROPRIETARY AND CONFIDENTIAL 248 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Register 7FH Signaling/E1 Control byte for Timeslot 31 :2 Addr 50 AM ISSUE 11 6: PMC-1970624 ug us - TPSC Indirect Registers 20H-3FH: PCM Data Control byte Type Function Default Bit 7 R/W INVERT Bit 6 R/W IDLE_DS0 Bit 5 R/W DMW Bit 4 R/W SIGNINV Bit 3 R/W TEST Bit 2 R/W LOOP X Bit 1 R/W ZCS0 X Bit 0 R/W ZCS1 X 2A Bit o Table 44 t, 20 The bits within each control byte are allocated as follows: 07 01 The "Timeslot" designation refers to the E1 assignment. The "Channel" designation refers to the T1 assignment. ,0 X ha cir on Th ur sd ay X X X bn INVERT: X ha d of When the INVERT bit is set to a logic 1, data from the BTPCM input is inverted for the duration of that channel. ab do u IDLE_DS0: ra s The INVERT bit only has effect in T1 mode. by When the IDLE_DS0 bit is set to a logic 1, data from the IDLE Code Byte replaces the BTPCM input data for the duration of that channel. The IDLE_DS0 bit controls insertion of the IDLE Code Byte only in T1 mode. Do wn l oa d ed When the NxDS0 mode is active, IDLE_DS0 also controls the generation of BTCLK. When IDLE_DS0 is a logic 0, data is inserted from the transmit backplane interface during that channel, and eight clock pulses are generated on BTCLK. When IDLE_DS0 is a logic 1, an IDLE code byte is inserted, and BTCLK is suppressed for the duration of that channel. PROPRIETARY AND CONFIDENTIAL 249 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 SIGNINV: 01 :2 6: When the SIGNINV bit is set to a logic 1, the most significant bit from the BTPCM input is inverted for that channel. 07 The SIGNINV bit only has effect in T1 mode. us - TPSC Transmit Data Conditioning ug Table 45 t, 20 The INVERT and SIGNINV can be used to produce the following types of inversions: SIGNINV Effect on PCM Channel Data 0 0 PCM Channel data is unchanged 1 0 All 8 bits of the PCM channel data are inverted 0 1 Only the MSB of the PCM channel data is inverted (SIGN bit inversion) 1 1 All bits EXCEPT the MSB of the PCM channel data is inverted (Magnitude inversion) on Th ur sd ay ,0 2A INVERT cir o DMW: bn ha When the DMW bit is set to a logic 1, the digital milliwatt pattern replaces the BTPCM input data for the duration of that channel. of The DMW bit only has effect in T1 mode. ha d TEST: by ab do u ra s When the TEST bit is set to a logic 1, channel data from the BTPCM input is either overwritten with a test pattern from the PRGD block or is routed to the PRGD block and compared against an expected test pattern. The RXPATGEN bit in the Pattern Generator/Detector Positioning/Control register determines whether the transmit data is overwritten or compared as shown in the following table: ed Table 46 RXPATGEN Description 0 X Channel data is not included in test pattern 1 1 Channel data is routed to PRGD and compared against expected test pattern 1 0 Channel data is overwritten with PRGD test pattern oa d TEST wn l Do - Transmit Test Pattern Modes PROPRIETARY AND CONFIDENTIAL 250 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 2A ug us t, 20 07 01 :2 6: 50 All the channels that are routed to the PRGD are concatenated and treated as a continuous stream in which pseudorandom are searched for. Similarly, all channels set to be overwritten with PRGD test pattern data are treated such that if the channels are subsequently extracted and concatenated, the PRBS appears in the concatenated stream. Pattern generation/detection can be enabled to work on only the first 7 bits of a channel (for Nx56 kbps fractional T1) using the Nx56k_DET and Nx56k_GEN bits in the Pattern Generator/Detector Positioning/Control register. The PRGD can also be enabled to work on the entire DS1, including framing bits, using the UNF_GEN and UNF_DET bits in the Pattern Generator/Detector Positioning/Control register. LOOP: Th ur sd ay ,0 The LOOP bit enables the DS0 loopback. When the LOOP bit is set to a logic 1, transmit data is overwritten with the corresponding channel data from the receive line. When the Receive Elastic Store (RX-ELST) is bypassed, it is used to align the receive line data to the transmit frame. When RX-ELST is enabled, however, it is unavailable to facilitate per-DS0 loopbacks. by ab do u ra s ha d of bn ha cir o on Data inversion, idle, loopback and test pattern insertion/checking are performed independent of the transmit framing format. DS0 loopback takes precedence over digital milliwatt pattern insertion. Next in priority is test pattern insertion, which, in turn, takes precedence over idle code insertion. Data inversion has the lowest priority. When test pattern checking is enabled, the transmit data is compared before DS0 loopback, digital milliwatt pattern insertion, idle code insertion or data inversion is performed. None of this prioritizing has any effect on the gapping of BTCLK in NxDS0 mode. That is, if both DS0 loopback and idle code insertion are enabled for a given channel while in NxDS0 mode, the DS0 will be looped-back, will not be overwritten with idle code, and BTCLK will be gapped out for the duration of the channel. Similarly, none of the prioritizing has any effect on the generation of test patterns from the PRGD, only on the insertion of that pattern. Thus, if both DMW and TEST are set for a given DS0, and RXPATGEN = 0, the test pattern from the PRGD will be overwritten with the digital milliwatt code. This same rule also applies to test patterns inserted via the UNF_GEN bit in the Pattern Generator/Detector Positioning/Control register. ed ZCS0, ZCS1: oa d The ZCS0 and ZCS1 bits select the zero code suppression used as follows: Do wn l Table 47 - Transmit Zero Code Suppression Formats ZCS0 ZCS1 Description 0 0 No Zero Code Suppression PROPRIETARY AND CONFIDENTIAL 251 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 ZCS1 Description 0 1 "Jammed bit 8" - Every bit 8 is forced to a one. This may be used for 56 kbit/s data service. This is the only code that should be inserted in E1 mode. 1 0 GTE Zero Code Suppression (Bit 8 of an all zero channel byte is replaced by a one, except in signaling frames where bit 7 is forced to a one.) 1 1 Bell Zero Code Suppression (Bit 7 of an all zero channel byte is replaced by a one.) - TPSC Indirect Registers 40H-5FH: IDLE Code byte ,0 Table 48 2A ug us t, 20 07 01 :2 6: 50 ZCS0 Type Function Default Bit 7 R/W IDLE7 Bit 6 R/W IDLE6 Bit 5 R/W IDLE5 Bit 4 R/W IDLE4 X Bit 3 R/W IDLE3 X Bit 2 R/W IDLE2 X Bit 1 R/W IDLE1 X Bit 0 R/W IDLE0 X X X X d of bn ha cir o on Th ur sd ay Bit ab do u ra s ha The contents of the IDLE Code byte register is substituted for the channel data on BTPCM when the IDLE_DS0 bit in the PCM Control Byte is set to a logic 1 in T1 mode or when the SUBS bit of the E1 Control Byte is logic 1 and the DS[0] bit of the E1 Control Byte is logic 0 in E1 mode. The IDLE Code is transmitted from MSB (IDLE7) to LSB (IDLE0). Function Default Bit 7 R/W SIGC[0]/SUBS X Bit 6 R/W SIGC[1]/DS[0] X Bit 5 R/W DS[1] X Bit 4 R/W SIGSRC X oa d wn l Do - TPSC Indirect Registers 60H-7FH: Signaling/E1 Control byte Type ed Bit by Table 49 PROPRIETARY AND CONFIDENTIAL 252 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Type Function Default Bit 3 R/W A' X Bit 2 R/W B' X Bit 1 R/W C' X Bit 0 R/W D' X t, 20 07 01 :2 6: Bit AM ISSUE 11 50 PMC-1970624 ug us The significance of the bits in these registers is dependent on whether the operating mode is T1 or E1. ,0 2A E1 Mode ay SUBS, DS[1], and DS[0]: Th ur sd The SUBS, DS[1], and DS[0] bits select one of the following data manipulations to be performed on the timeslot: - Transmit Per-timeslot Data Manipulation on Table 50 DS[1] Function 0 0 0 OFF - no change to PCM timeslot data 0 0 1 ADI - data inversion on timeslot bits 1, 3, 5, 7 0 1 0 0 1 1 1 0 X 1 1 cir ha bn ADI - data inversion on timeslot bits 2, 4, 6, 8 ab do u ra s ha d of INV - data inversion on all timeslot bits 1 Data substitution on - IDLE code replaces BTPCM timeslot data 0 Data substitution on - A-Law digital pattern* replaces BTPCM timeslot data. 1 Data substitution on - -Law digital pattern* replaces BTPCM timeslot data. by 1 o SUBS DS[0] oa d ed *Note: The A-Law digital milliwatt pattern used is that defined in Recommendation G.711 for A-law: Do wn l Table 51 - A-Law Digital Milliwatt Pattern Bit 1 Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 Bit 8 0 0 1 1 0 1 0 0 PROPRIETARY AND CONFIDENTIAL 253 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Bit 2 Bit 3 Bit 4 Bit 5 Bit 6 Bit 7 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 1 1 0 1 1 0 1 1 0 1 1 0 1 0 0 0 1 0 1 0 0 1 0 1 1 0 01 :2 6: Bit 1 AM ISSUE 11 Bit 8 50 PMC-1970624 1 1 0 0 0 0 1 0 0 1 1 0 0 2A ug us t, 20 07 0 sd ay ,0 *Note: The -Law digital milliwatt pattern used is that defined in Recommendation G.711 for -law: Bit 2 Bit 3 Bit 4 Bit 6 Bit 7 Bit 8 0 0 0 1 1 1 1 0 0 0 0 0 1 0 1 1 0 0 0 0 1 0 1 1 0 0 0 1 1 1 1 0 1 0 0 1 1 1 1 0 1 0 0 0 1 0 1 1 1 0 0 0 1 0 1 1 1 0 0 1 1 1 1 0 on o cir ha bn of ab do u ra s Th Bit 5 d Bit 1 ur - -Law Digital Milliwatt Pattern ha Table 52 SIGSRC: Do wn l oa d ed by The SIGSRC bit is valid only if Channel Associated Signaling (CAS) is selected in the E1-TRAN Configuration Register; otherwise, it is ignored. When valid, the SIGSRC bit selects the source of the timeslot signaling bits: if SIGSRC is a logic 0, the signaling bits are taken from the incoming BTSIG stream in the format specified by the SIGEN and DLEN bits in the E1-TRAN Configuration Register; if SIGSRC is a logic 1, the signaling bits are taken from the A',B',C', and D' bit . PROPRIETARY AND CONFIDENTIAL 254 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 T1 Mode Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 Signaling insertion is controlled by the SIGC[1:0] bits. The source of the signaling bits is determined by SIGC0: when SIGC0 is set to a logic 1, signaling data is taken from the A', B', C', and D' bits; when SIGC0 is set to logic 0, signaling data is taken from the A,B,C, and D bit locations on the BTSIG input. Signaling insertion is controlled by SIGC1: when SIGC1 is set to a logic 1 and ESF, SF, or SLC(R)96 transmit format is selected, insertion of signaling bits is enabled; when SIGC1 is set to logic 0, the insertion of signaling bits is disabled. For SF and SLC(R)96 formats, the C' and D' or C and D bits from Signaling Control byte or BTSIG, respectively, are inserted into the A and B signaling bit positions of every second superframe that is transmitted. It is assumed that C=A and D=B. The A',B',C', and D' bits do not pass through the Signaling Aligner block. When signaling insertion via the A',B',C', and D' bits is enabled, changing the signaling state by writing to the TPSC can cause the transmit stream to briefly (for one superframe or extended superframe) carry a signaling state that is neither the new or the old signaling state (e.g., may have the A bit from the new state but the B bit from the old state). PROPRIETARY AND CONFIDENTIAL 255 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 R/W Reserved Bit 1 R/W IND Bit 0 R/W PCCE :2 Default us t, 20 07 01 Function ug Type 2A Bit 6: Register 070H: RPSC Configuration 0 sd ay ,0 0 0 on Th ur This register allows selection of the microprocessor read access type and output enable control for the Receive Per-channel Serial Controller. Reserved: cir o The Reserved bit must be programmed to logic 0 for normal operation. ha IND: d of bn The IND bit controls the microprocessor access type: either indirect or direct. The IND bit must be set to logic 1 for proper operation. When the COMET is reset, the IND bit is set low, disabling the indirect access mode. ra s ha PCCE: Do wn l oa d ed by ab do u The PCCE bit enables the per-channel functions. When the PCCE bit is set to a logic 1, the Data Trunk Conditioning Code byte and Signaling Trunk Conditioning Code byte are enabled to modify the received data and extracted signaling data streams (visible on BRPCM and BRSIG, if selected) under direction of each channel's PCM Control byte. When the PCCE bit is set to logic 0, the per-channel functions are disabled. PROPRIETARY AND CONFIDENTIAL 256 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default R BUSY X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 Unused 01 07 20 t, us ug X ,0 X ay Bit 7 :2 Type sd Bit 6: Register 071H: RPSC P Access Status X Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur The BUSY bit in the Status register is high while a P access request is in progress. The BUSY bit goes low timed to an internal high-speed clock rising edge after the access has been completed. During normal operation, the Status Register should be polled until the BUSY bit goes low before another P access request is initiated. A P access request is typically completed within 640 ns. PROPRIETARY AND CONFIDENTIAL 257 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W R/WB 0 Bit 6 R/W A6 0 Bit 5 R/W A5 0 Bit 4 R/W A4 0 Bit 3 R/W A3 0 Bit 2 R/W A2 Bit 1 R/W A1 Bit 0 R/W A0 ug us t, 20 07 01 :2 Bit 2A 6: Register 072H: RPSC Channel Indirect Address/Control 0 sd ay ,0 0 0 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur This register allows the P to access the internal RPSC registers addressed by the A[6:0] bits and perform the operation specified by the R/WB bit. Writing to this register with a valid address and R/WB bit initiates an internal P access request cycle. The R/WB bit selects the operation to be performed on the addressed register: when R/WB is set to a logic 1, a read from the internal RPSC register is requested; when R/WB is set to a logic 0, an write to the internal RPSC register is requested. PROPRIETARY AND CONFIDENTIAL 258 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W D7 0 Bit 6 R/W D6 0 Bit 5 R/W D5 0 Bit 4 R/W D4 0 Bit 3 R/W D3 0 Bit 2 R/W D2 Bit 1 R/W D1 Bit 0 R/W D0 ug us t, 20 07 01 :2 Bit 2A 6: Register 073H: RPSC Channel Indirect Data Buffer 0 sd ay ,0 0 0 of bn ha cir o on Th ur This register contains either the data to be written into the internal RPSC registers when a write request is initiated or the data read from the internal RPSC registers when a read request has completed. During normal operation, if data is to be written to the internal registers, the byte to be written must be written into this Data register before the target register's address and R/WB=0 is written into the Address/Control register, initiating the access. If data is to be read from the internal registers, only the target register's address and R/WB=1 is written into the Address/Control register, initiating the request. After 640 ns, this register will contain the requested data byte. ab do u ra s ha d The internal RPSC registers control the per-channel functions on the Receive PCM data provide the per-channel Data Trunk Conditioning Code and provide the per-channel Signaling Trunk Conditioning Code. The functions are allocated within the registers shown in Table 53: Table 53 Addr by 20H Register PCM Data Control byte for Timeslot 0 PCM Data Control byte for Channel 1/Timeslot 1 22H PCM Data Control byte for Channel 2/Timeslot 2 oa d ed 21H wn l Do - RPSC Indirect Register Map 37H * * * * PCM Data Control byte for Channel 23/Timeslot 23 PROPRIETARY AND CONFIDENTIAL 259 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Register 38H PCM Data Control byte for Channel 24/Timeslot 24 39H PCM Data Control byte for Timeslot 25 * PCM Data Control byte for Timeslot 30 3FH PCM Data Control byte for Timeslot 31 40H Data Trunk Conditioning byte for Timeslot 0 41H Data Trunk Conditioning byte for Channel 1/Timeslot 1 42H Data Trunk Conditioning byte for Channel 2/Timeslot 2 ay ,0 2A ug us t, 3EH sd * ur * * * Data Trunk Conditioning byte for Channel 23/Timeslot 23 58H Data Trunk Conditioning byte for Channel 24/Timeslot 24 59H Data Trunk Conditioning byte for Timeslot 25 cir o on Th 57H * ha * * bn * Data Trunk Conditioning byte for Timeslot 30 5FH Data Trunk Conditioning byte for Timeslot 31 61H Signaling Trunk Conditioning byte for Channel 1/Timeslot 1 62H Signaling Trunk Conditioning byte for Channel 2/Timeslot 2 * Signaling Trunk Conditioning byte for Channel 23/Timeslot 23 78H Signaling Trunk Conditioning byte for Channel 24/Timeslot 24 ed by 77H * ab do u * ra s ha d of 5EH * Signaling Trunk Conditioning byte for Timeslot 25 wn l oa d 79H Do 01 * 07 * 20 * :2 Addr 50 AM ISSUE 11 6: PMC-1970624 * * * * 7EH Signaling Trunk Conditioning byte for Timeslot 30 7FH Signaling Trunk Conditioning byte for Timeslot 31 PROPRIETARY AND CONFIDENTIAL 260 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 The "Timeslot" designation refers to the E1 assignment. The "Channel" designation refers to the T1 assignment. 01 :2 The bits within each control byte are allocated as follows: Type Function Default Bit 7 R/W TEST X Bit 6 R/W DTRKC X Bit 5 R/W STRKC X Bit 4 R/W DMW Bit 3 R/W DMWALAW Bit 2 R/W SIGNINV us ug 2A Unused ay sd ur Bit 0 X on Th Unused ,0 X Bit 1 X X X cir o TEST: t, Bit 07 - RPSC Indirect Registers 20H-3FH: PCM Data Control byte 20 Table 54 ha d of bn ha When the TEST bit is set to a logic 1, receive channel data is either overwritten with a test pattern from the PRGD block or is routed to the PRGD block and compared against an expected test pattern. The RXPATGEN bit in the Pattern Generator/Detector Positioning/Control register determines whether the transmit data is overwritten or compared as shown in the following table: 0 by 1 RXPATGEN ab do u TEST - Receive Test Pattern Modes Description X Channel data is not included in test pattern 0 Channel data is routed to PRGD and compared against expected test pattern 1 Channel data is overwritten with PRGD test pattern oa d ed 1 ra s Table 55 Do wn l All the channels that are routed to the PRGD are concatenated and treated as a continuous stream in which pseudorandom are searched for. Similarly, all channels set to be overwritten with PRGD test pattern data are treated such that if the channels are subsequently extracted and concatenated, the PRBS appears in the concatenated stream. Pattern generation/detection can be enabled to PROPRIETARY AND CONFIDENTIAL 261 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 work on only the first 7 bits of a channel (for Nx56 kbps fractional T1) using the Nx56k_DET and Nx56k_GEN bits in the Pattern Generator/Detector Positioning/Control register. The PRGD can also be enabled to work on the entire DS1, including framing bits, using the UNF_GEN and UNF_DET bits in the Pattern Generator/Detector Positioning/Control register. 20 DTRKC: ug us t, When the DTRKC bit is set to a logic 1, data from the Data Trunk Conditioning Code Byte contained within the RPSC indirect registers replaces the BRPCM output data for the duration of that channel. ay ,0 2A When the Receive Backplane Configuration register selects a NxDS0 mode, the DTRKC bit also controls BRCLK generation. If DTRKC is a logic 1, BRCLK is held low for the duration of the channel. sd STRKC: on Th ur When the STRKC bit is set to a logic 1, data from the Signaling Trunk Conditioning Code Byte contained within the RPSC indirect registers replaces the BRSIG output data for the duration of that channel. o DMW: of bn ha cir When the DMW bit is set to a logic 1, a digital milliwatt pattern replaces the BRPCM output data for the duration of that channel. The particular digital milliwatt pattern used, A-law or u-law, is selected by the DMWALAW bit of this register. d DMWALAW: ab do u ra s ha When the DMWALAW bit is set to a logic 1, the digital milliwatt pattern replacing the BRPCM output data for the duration of that channel is the A-law pattern (see Table 51). When the DMWALAW bit is set to a logic 0, the digital milliwatt pattern replacing the BRPCM output data for the duration of that channel is the -law pattern (see Table 52). by SIGNINV: In T1 mode, the RINV[1] of the and SIGNINV bits can be used to invert data as shown in Table 37: Do wn l oa d ed When the SIGNINV bit is set to a logic 1, the most significant bit of the data output on the BRPCM pin is the inverse of the received data most significant bit for that channel. PROPRIETARY AND CONFIDENTIAL 262 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 6: 50 - RPSC Indirect Registers 40H-5FH: Data Trunk Conditioning Type Function Default Bit 7 R/W DTRK7 X Bit 6 R/W DTRK6 X Bit 5 R/W DTRK5 X Bit 4 R/W DTRK4 X Bit 3 R/W DTRK3 X Bit 2 R/W DTRK2 Bit 1 R/W DTRK1 Bit 0 R/W DTRK0 ug us t, 20 07 01 :2 Bit 2A Table 56 Code byte COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 ,0 X X ur sd ay X o on Th The contents of the Data Trunk Conditioning Code byte register is substituted for the channel data on BRPCM when the DTRKC bit in the PCM Control Byte is set to a logic 1. The Data Trunk Conditioning Code is transmitted from MSB (DTRK7) to LSB (DTRK0). Type Default Unused X Unused X Unused X Unused X R/W A' X R/W B' X Bit 1 R/W C' X R/W D' X of Function ed Bit bn ha cir Table 57 - RPSC Indirect Registers 61H-7FH: Signaling Trunk Conditioning byte d Bit 7 ha Bit 6 Bit 3 by Bit 2 ab do u Bit 4 ra s Bit 5 oa d Bit 0 Do wn l The contents of the Signaling Trunk Conditioning Code byte register is substituted for the channel signaling data on BRSIG when the STRKC bit is set to a logic 1. The Signaling Trunk Conditioning Code is placed in least significant nibble of the channel byte. PROPRIETARY AND CONFIDENTIAL 263 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X 0 Bit 4 R/W U1 0 Bit 3 R/W U2 0 Bit 2 R/W CONT_CRC Bit 1 R/W INTE Bit 0 R/W AUTOUPDATE 07 20 R t, R/W 2A Bit 5 :2 Default 01 Function us Type ug Bit 6: Register 078H: T1 APRM Configuration/Control 0 sd 0 Th ur AUTOUPDATE: ay ,0 0 ha cir o on The AUTOUPDATE bit controls the automatic updating of the performance report on a per second basis. If this bit is set to a logic 1, the Performance Report Messages are generated and updated once a second. When AUTOUPDATE is set to a logic 0, the performance report is updated manually by toggling the MAN_LOAD register bit. bn INTE: ab do u CONT_CRC: ra s ha d of The INTE bit enables the interrupt output pin. When INTE is set to a logic 1, a logic 1 in the INTR bit in the T1 APRM Interrupt Status register asserts the INTB output low. INTR is disabled from generating interrupts when INTE is set to a logic 0. ed by The CONT_CRC is the Continuous CRC bit. When set to logic 1, the SE and G6 bits in the Performance Report are set to1 and G1, G2, G3, G4, G5 and FE are set to 0. When reset to logic 0, the Gn (n = [1..5]), FE and SE bits are set according to the received CRC errors. The U1, U2 bits are under study for synchronization. Their default value is 0. These bits require two updating cycles before they are included in the performance report. Do wn l oa d U1, U2: PROPRIETARY AND CONFIDENTIAL 264 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 R: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: The R bit is a reserved bit in the performance report. The default value is 0. This bit requires two updating cycles before it is included in the performance report. PROPRIETARY AND CONFIDENTIAL 265 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 R/W ug us t, 20 07 01 :2 Function X ,0 X ay Type MAN_LOAD 0 Th ur MAN_LOAD: sd Bit 6: Register 079H: T1 APRM Manual Load Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The MAN_LOAD bit is used to load the next Performance Report into the holding registers. This bit is enabled when AUTOUPDATE is set to a logic 0. In manual PR generation mode, it is important to poll the MAN_LOAD bit to ensure that the previous Performance Report transmission has been transmitted. When the microprocessor requests a Performance Report, the MAN_LOAD bit is set high. When the last bit of the Performance Report has been transmitted, the MAN_LOAD bit is reset to a logic 0. PROPRIETARY AND CONFIDENTIAL 266 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 R ug us t, 20 07 01 :2 Function X ,0 X ay Type INTR sd Bit 6: Register 07AH: T1 APRM Interrupt Status Th ur INTR: 0 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on The interrupt (INTR) bit is set to logic 1 on one second boundaries, to signal that the one second data is ready. If the INTE bit is a logic 1, the INTB output is asserted low when INTR is logic 1. INTR is cleared when this register is read. PROPRIETARY AND CONFIDENTIAL 267 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W SAPI[5] 0 Bit 6 R/W SAPI[4] 0 Bit 5 R/W SAPI[3] 1 Bit 4 R/W SAPI[2] 1 Bit 3 R/W SAPI[1] 1 Bit 2 R/W SAPI[0] Bit 1 R/W C/R Bit 0 R/W EA ug us t, 20 07 01 :2 Bit 2A 6: Register 07BH: T1 APRM One Second Content Octet 2 0 sd ay ,0 0 Th ur SAPI[5:0]: 0 on The SAPI[5:0] represent the service access point identifier bits. The value of SAPI[5:0] in the performance report is constant i.e., SAPI = 14. cir o C/R: bn ha The C/R bit is the Command/Response bit. The value of C/R from the CI is set to a logic 0 and the value of the C/R bit from the carrier is set to a logic 1. of EA: Do wn l oa d ed by ab do u ra s ha d The EA bit is the Extended Address bit in the second octet. The EA bit defaults to logic 0. PROPRIETARY AND CONFIDENTIAL 268 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W TEI[6] 0 Bit 6 R/W TEI[5] 0 Bit 5 R/W TEI[4] 0 Bit 4 R/W TEI[3] 0 Bit 3 R/W TEI[2] 0 Bit 2 R/W TEI[1] Bit 1 R/W TEI[0] Bit 0 R/W EA ug us t, 20 07 01 :2 Bit 2A 6: Register 07CH: T1 APRM One Second Content Octet 3 0 sd ay ,0 0 Th ur TEI[6:0]: 1 on The TEI[6:0] bits represent the terminal endpoint identifier. The TEI[6:0] default to logic 0. cir o EA: Do wn l oa d ed by ab do u ra s ha d of bn ha The EA bit is the Extended Address bit in the third octet. The EA bit defaults to logic 1. PROPRIETARY AND CONFIDENTIAL 269 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W CONTROL[7] 0 Bit 6 R/W CONTROL[6] 0 Bit 5 R/W CONTROL[5] 0 Bit 4 R/W CONTROL[4] 0 Bit 3 R/W CONTROL[3] 0 Bit 2 R/W CONTROL[2] Bit 1 R/W CONTROL[1] Bit 0 R/W CONTROL[0] 01 07 20 t, us ug 0 sd ay ,0 1 1 Th ur CONTROL[7:0]: :2 Bit 2A 6: Register 07DH: T1 APRM One Second Content Octet 4 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on This register set the value of the CONTROL field in the performance report and defaults to "00000011". It is inserted into the fourth octet of the performance report. PROPRIETARY AND CONFIDENTIAL 270 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R G3 X Bit 6 R LV X Bit 5 R G4 X Bit 4 R U1 X Bit 3 R U2 X Bit 2 R G5 Bit 1 R SL 2A Bit 0 R G6 ug us t, 20 07 01 :2 Type X ay ,0 X sd Bit 6: Register 07EH: T1 APRM One Second Content MSB (Octet 5) X on Th ur The contents of this register represent the values encoded in the latest performance report transmitted. This register is updated coincident with the assertion of the INTR bit of the T1 APRM Interrupt Status register. cir o G3: bn ha This bit is set to a logic-1, if the number of CRC error events in a one second interval is greater than 5 and less than or equal to 10 (i.e., 5 < CRC error events 10). of LV: ra s ha d This bit is set to a logic 1, if the number of Line code violation events in a one second interval is greater than or equal to 1 (i.e., LCV 1). ab do u G4: by This bit is set to a logic 1, if the number of CRC error events in a one second interval is greater than 10 and less than or equal to 100 (i.e., 10 21 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd 10110-11111 PROPRIETARY AND CONFIDENTIAL 356 Reserved PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X OVRFLW Bit 1 R/W Reserved Bit 0 R/W Reserved 07 20 t, us ug 2A R X 0 ,0 Bit 2 :2 Default 01 Function ay Type sd Bit 6: Register 0F1H: XLPG Control/Status 1 on Th ur When the TUNI bit of the Transmit Line Interface Configuration register is a logic 1, this register is held reset. OVRFLW: ab do u ra s ha d of bn ha cir o The overflow detection value bit (OVRFLW) indicates the presence or absence of an overflow condition in the waveform computation pipeline. An overflow occurs when the sum of the five unit interval (UI) samples exceeds the maximum D/A value. The XLPG detects overflows and saturates the output value to minimize their impact on the output signal. Overflows can easily be eliminated by changing the waveform programming. This status bit is set to logic 1 when an overflow condition is detected and it is reset to logic 0 only when this register is read. It is suggested to read this register twice after the programming of a new waveform and transmission of data to ensure the maximum output amplitude is never exceeded. Reserved: Do wn l oa d ed by The Reserved bits must remain in their default state for correct operation. PROPRIETARY AND CONFIDENTIAL 357 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W SAMPLE[4] 0 Bit 6 R/W SAMPLE[3] 0 Bit 5 R/W SAMPLE[2] 0 Bit 4 R/W SAMPLE[1] 0 Bit 3 R/W SAMPLE[0] 0 Bit 2 R/W UI[2] Bit 1 R/W UI[1] Bit 0 R/W UI[0] :2 Type 2A ug us t, 20 07 01 Bit 6: Register 0F2H: XLPG Pulse Waveform Storage Write Address 0 sd ay ,0 0 0 on Th ur When the TUNI bit of the Transmit Line Interface Configuration register is a logic 1, this register is held reset. UI[2:0]: d ha SAMPLE[4:0]: of bn ha cir o The pulse waveform write address is composed of a unit interval selector and a sample selector. The unit interval selector (UI[2:0]) selects which unit interval is being written for a given sample. There are 5 unit intervals, numbered from 0 to 4. UI[2:0] can take the values 0H, 1H, 2H, 3H and 4H. The values 5H, 6H and 7H are undefined. ab do u ra s The pulse waveform write address is composed of a unit interval selector and a sample selector. The sample selector (SAMPLE[4:0]) selects which sample is being written for a given unit interval. There are 24 samples, numbered from 0 to 23. SAMPLE[4:0] can thus have any value from 00H to 17H. The values from 18H to 1FH are undefined. Do wn l oa d ed by See the Operation section for more details on setting up waveform templates. PROPRIETARY AND CONFIDENTIAL 358 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default W WDAT[6] X Bit 5 W WDAT[5] X Bit 4 W WDAT[4] X Bit 3 W WDAT[3] X Bit 2 W WDAT[2] Bit 1 W WDAT[1] Bit 0 W WDAT[0] ug us t, 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 0F3H: XLPG Pulse Waveform Storage Data X sd ay ,0 X X on Th ur When the TUNI bit of the Transmit Line Interface Configuration register is a logic 1, this register is held reset. WDAT[6:0]: ra s ha d of bn ha cir o This register allows software to program the contents of any one of the 120 internal waveform template registers, addressed by the UI[2:0] and SAMPLE[4:0] bits in the Pulse Waveform Storage Write Address register. When accessing the internal waveform storage registers, the address of the desired register must first be written to the Indirect Address register (the XLPG Pulse Waveform Storage Write Address register). Then, by writing the Indirect Data register (the XLPG Pulse Waveform Storage Data register), the microprocessor can write the data to the selected write address. ed by ab do u The value written to the internal pulse waveform storage registers is contained in the signed WDAT[6:0] bits. A signed representation is used (by opposition to a two's complement representation) to make the programming easier. WDAT[6] is the sign bit, WDAT[5] is the most significant data bit and WDAT[0] is the least significant data bit. The data value thus can range from -62 to +63 (-63 is not a valid value due to subsequent conversion into a two's complement representation). Do wn l oa d See the Operation section for more details on setting up custom waveform templates. PROPRIETARY AND CONFIDENTIAL 359 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R/W TNC[6] 0 Bit 5 R/W TNC[5] 0 Bit 4 R/W TNC[4] 0 Bit 3 R/W TNC[3] 0 Bit 2 R/W TNC[2] Bit 1 R/W TNC[1] Bit 0 R/W TNC[0] ug us t, 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 0F4H: XLPG Analog Test Negative Control 0 sd ay ,0 0 0 on Th ur When the TUNI bit of the Transmit Line Interface Configuration register is a logic 1, this register is held reset. cir o TNC[6:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha This register controls the nDAC absolute current (both "blowing" the fuses and the software override of the fuses) of the analog transmit line interface unit. TNC[1:5] adjust the offset in steps of 0.78125%, TNC[6] controls the direction (0 is positive, 1 is negative) and TNC[0] is the enable (active low). When TNC[0] is logic 0 and the TRIMF input pin is high, the fuse(s) (as indicated by TNC[1:6]) will be blown. Note that the device must be in analog test mode to enable this control. When TRIMF is low and TNC[0] is logic 0, then TNC[1:6] override the fuses (note this is independent of being in analog test mode). PROPRIETARY AND CONFIDENTIAL 360 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Unused X :2 Default R/W TPC[6] 0 Bit 5 R/W TPC[5] 0 Bit 4 R/W TPC[4] 0 Bit 3 R/W TPC[3] 0 Bit 2 R/W TPC[2] Bit 1 R/W TPC[1] Bit 0 R/W TPC[0] ug us t, 20 Bit 6 2A Bit 7 Function 01 Type 07 Bit 6: Register 0F5H: XLPG Analog Test Positive Control 0 sd ay ,0 0 0 on Th ur When the TUNI bit of the Transmit Line Interface Configuration register is a logic 1, this register is held reset. TPC[6:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o This register controls the pDAC absolute current (both "blowing" the fuses and the software override of the fuses) of the analog transmit line interface unit. TPC[1:5] adjust the offset in steps of 0.78125%, TPC[6] controls the direction (0 is positive, 1 is negative) and TPC[0] is the enable (active low). When TPC[0] is logic 0 and the TRIMF input pin is high, the fuse(s) (as indicated by TPC[1:6]) will be blown. Note that the device must be in analog test mode to enable this control. When TRIMF is low and TPC[0] is logic 0, then TPC[1:6] override the fuses (note this is independent of being in analog test mode). PROPRIETARY AND CONFIDENTIAL 361 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Default Bit 7 Unused X Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused 2A Bit 0 R/W ug us t, 20 07 01 :2 Function X ,0 X ay Type FDSB sd Bit 6: Register 0F6H: XLPG Fuse Data Select 0 on Th ur When the TUNI bit of the Transmit Line Interface Configuration register is a logic 1, this register is held reset. FDSB: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o This register selects between microprocessor data (FDSB is logic 1) or the value burned into the fuses of the transmit line interface unit (FDSB is logic 0) as the inputs to the XLPG Analog Test Negative Control Register and the XLPG Analog Test Positive Control Register. To write the fuse data into the XLPG Analog Test Negative Control Register and the XLPG Analog Test Positive Control Register, TPC[0] and TNC[0], respectively, must be set to logic 1 and the XLPG Analog Test Negative Control Register and the XLPG Analog Test Positive Control Register must each be written to twice consecutively. (The first write is to activate the outputs of the transmit line interface unit valid, and the second write copies the fuse data into the register.) TPC[0] and TNC[0] should be cleared to lower the likelihood of fuse re-growth. PROPRIETARY AND CONFIDENTIAL 362 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R ALOSI X Bit 6 R ALOSV X Bit 5 R/W ALOSE 0 Bit 4 R/W SQUELCHE 0 Bit 3 R/W IDDQ_EN 0 Bit 2 R/W DB_VALID Reserved sd R/W 01 07 20 t, us X ,0 Unused Bit 0 ug X ay Bit 1 :2 Type 2A Bit 6: Register 0F8H: RLPS Configuration and Status 1 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. Reserved: cir o The Reserved bit must be programmed to logic 1 for correct operation. ha DB_VALID: ra s IDDQ_EN: ha d of bn The DB_VALID bit indicates if the adaptive equalizer has stabilized. This bit is set if the CABLELOSS signal has not changed by more than 2dB (or +/-8 steps in the RAM table) in more than the count of sampling periods selected by the VALID_PER[1:0] bits of the RLPS Equalizer Configuration register. by ab do u The IDDQ enable bit (IDDQ_EN) is used to configure the analog receiver for IDDQ tests. When IDDQ_EN is a logic 1, or the IDDQEN bit in the Master Test register (00BH) is a logic 1, the digital outputs of the analog receiver are pulled to ground. ed SQUELCHE: Do wn l oa d The output data squelch enable (SQUELCHE) allows control of data squelching in response to an analog LOS of signal condition. When SQUELCHE is set to logic 1, the recovered data are forced to all-zeros if the ALOSV register bit is asserted. When SQUELCHE is set to logic 0, squelching is disabled. PROPRIETARY AND CONFIDENTIAL 363 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 ALOSE: 20 07 01 :2 6: The loss of signal interrupt enable bit (ALOSE) enables the generation of device level interrupt on a change of Loss of Signal status. When ALOSE is a logic 1, an interrupt is generated by asserting INTB low when there is a change of the ALOSV status. When ALOSE is set to logic 0, interrupts are disabled. t, ALOSV: 2A ug us The loss of signal value bit (ALOSV) indicates the loss of signal alarm state. This status bit is available for both short haul mode and long haul modes of operation. ,0 ALOSI: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay The loss of signal interrupt bit (ALOSI) is a logic 1 whenever the Loss of Signal indicator state (ALOSV) changes from a logic 0 to a logic 1. This bit is cleared when this register is read. PROPRIETARY AND CONFIDENTIAL 364 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 X 0 Bit 5 R/W CLR_THR[1] 0 Bit 4 R/W CLR_THR[0] 0 Unused X DET_THR[2] Bit 1 R/W DET_THR[1] Bit 0 R/W DET_THR[0] 0 0 ,0 R/W ay Bit 2 sd Bit 3 07 CLR_THR[2] 20 R/W 2A Bit 6 :2 Unused 01 Default t, Bit 7 Function us Type ug Bit 6: Register 0F9H: RLPS ALOS Detection/Clearance Threshold 0 - ALOS Detection/Clearance Thresholds o Table 70 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. ha bn of d 000 001 010 Signal level (dB) cir THR ab do u ra s ha 011 100 101 110 111 9 14.5 20 Detection/ Clearance Clearance Detection and Clearance 22 25 30 Detection and Clearance 31 35 Detection by DET_THR[2:0]: Do wn l oa d ed DET_THR[2:0] references one of the threshold settings in Table 70 as the ALOS detection criteria. If the incoming signal level is less than or equal to that threshold for N consecutive pulse period, (where N = 16 * the value stored in the RLPS ALOS Detection Period Register) ALOS is declared and interrupt is set. The DET_THR[2:0] bits must be programmed to the same value as the CLR_THR[2:0] bits. PROPRIETARY AND CONFIDENTIAL 365 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 CLR_THR[2:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 07 01 :2 6: CLR_THR[2:0] references one of the threshold settings listed in Table 70 as the ALOS clearance criteria. ALOS is cleared when the incoming signal level is greater than or equal to dB below nominal for N consecutive pulse intervals, where N = 16 * CLR_PER stored in the RLPS ALOS Clearance Period Register. The CLR_THR[2:0] bits must be programmed to the same value as the DET_THR[2:0] bits. PROPRIETARY AND CONFIDENTIAL 366 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W DET_PER[7] 0 Bit 6 R/W DET_PER[6] 0 Bit 5 R/W DET_PER[5] 0 Bit 4 R/W DET_PER[4] 0 Bit 3 R/W DET_PER[3] 0 Bit 2 R/W DET_PER[2] Bit 1 R/W DET_PER[1] Bit 0 R/W DET_PER[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 0FAH: RLPS ALOS Detection Period 0 sd ay ,0 0 1 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. DET_PER[7:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o This register specifies the time duration that the incoming signal level has to remain below the detection threshold in order for the ALOS to be issued. This duration is equal to DET_PER * 16 number of pulse intervals, the resulting range is from 16 to 4080 and thus compliant with all the presently available E1/T1 ALOS detection standards/ recommendations. PROPRIETARY AND CONFIDENTIAL 367 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W CLR_PER[7] 0 Bit 6 R/W CLR_PER[6] 0 Bit 5 R/W CLR_PER[5] 0 Bit 4 R/W CLR_PER[4] 0 Bit 3 R/W CLR_PER[3] 0 Bit 2 R/W CLR_PER[2] Bit 1 R/W CLR_PER[1] Bit 0 R/W CLR_PER[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 0FBH: RLPS ALOS Clearance Period 0 sd ay ,0 0 1 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. CLR_PER[7:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o This register specifies the time duration that the incoming signal level has to remain above the clearance threshold in order for the ALOS to be cleared. This duration is equal to CLR_PER * 16 number of pulse intervals resulting in a range from 16 to 4080 and thus compliant with all the presently available E1/T1 ALOS clearance standards/ recommendations. PROPRIETARY AND CONFIDENTIAL 368 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W EQ_ADDR[7] 0 Bit 6 R/W EQ_ADDR[6] 0 Bit 5 R/W EQ_ADDR[5] 0 Bit 4 R/W EQ_ADDR[4] 0 Bit 3 R/W EQ_ADDR[3] 0 Bit 2 R/W EQ_ADDR[2] Bit 1 R/W EQ_ADDR[1] Bit 0 R/W EQ_ADDR[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 0FCH: RLPS Equalization Indirect Address 0 sd ay ,0 0 0 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. EQ_ADDR [7:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o Writing to this register initiates an internal uP access request cycle to the RAM. Depending on the setting of the RWB bit inside register 0FDH, a read or a write will be performed. During a write cycle, the indirect data bits located in registers 0D8H to 0DBH is written into the RAM. For a read request, the content of the addressed RAM location is written into registers 0D8H to 0DBH. This register should be the last register to be written for a uP access. A waiting period of three line rate cycles is needed between the time this register is written to the time the next indirect data bits in registers 0D8H to 0DBH are written. PROPRIETARY AND CONFIDENTIAL 369 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W RWB 1 Bit 6 Unused X Bit 5 Unused X Bit 4 Unused X Bit 3 Unused X Bit 2 Unused Bit 1 Unused Bit 0 Unused ug us t, 20 07 01 :2 Bit 2A 6: Register 0FDH: RLPS Equalization Read/WriteB Select X sd ay ,0 X X on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. RWB: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o This bit selects the operation to be performed on the RAM: when RWB is `1', a read from the equalization RAM is requested; when RWB is set to `0', a write to the RAM is desired. PROPRIETARY AND CONFIDENTIAL 370 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Type Function Default Bit 7 R/W LOCATION[7] 0 Bit 6 R/W LOCATION[6] 0 Bit 5 R/W LOCATION[5] 0 Bit 4 R/W LOCATION[4] 0 Bit 3 R/W LOCATION[3] 0 Bit 2 R/W LOCATION[2] Bit 1 R/W LOCATION[1] Bit 0 R/W LOCATION[0] ug us t, 20 07 01 :2 Bit 2A 6: Register 0FEH: RLPS Equalizer Loop Status and Control 0 sd ay ,0 0 0 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. LOCATION[7:0]: Do wn l oa d ed by ab do u ra s ha d of bn ha cir o Writing to this register overwrites a counter which serves as the read address to the equalization RAM. Reading this register returns the current value of the counter PROPRIETARY AND CONFIDENTIAL 371 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 Function Default Bit 7 R/W VALID_PER[1] 0 Bit 6 R/W VALID_PER[0] 0 Bit 5 Unused X Bit 4 Unused X 0 Bit 1 R/W EQ_FREQ[1] Bit 0 R/W EQ_FREQ[0] 07 20 t, us EQ_FREQ2] ug R/W 2A Bit 2 0 1 ,0 Reserved ay R/W sd Bit 3 :2 Type 01 Bit 6: Register 0FFH: RLPS Equalizer Configuration 1 on Th ur When the RUNI bit of the Receive Line Interface Configuration register is a logic 1, this register is held reset. EQ_FREQ[2:0]: - Equalization Feedback Frequencies bn Table 71 ha cir o The EQ_FREQ[2:0] field selects the frequency of the EQ feedback loop as indicated by Table 71. d of EQ_FREQ[2:0] ed by ab do u ra s ha 000 001 010 011 100 101 110 111 EQ Feedback Frequency T1 mode E1 mode 24.125 kHz 32.000 kHz 12.063 kHz 16.000 kHz 8.0417 kHz 10.667 kHz 6.0313 kHz 8.0000 kHz 4.8250 kHz 6.40 kHz 4.0208 kHz 5.333 kHz 3.4464 kHz 4.5714 kHz 3.0156 kHz 4.0 kHz The Reserved bit must be programmed to logic 1 for correct operation. Note that this bit defaults to logic 0. Do wn l oa d Reserved: PROPRIETARY AND CONFIDENTIAL 372 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 VALID_PER[1:0]: Number of periods 32 64 128 256 Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us VALID_PER 00 01 10 11 PROPRIETARY AND CONFIDENTIAL 20 - Valid Period t, Table 72 07 01 :2 6: The VALID_PER[1:0] bits select the length of time that the dB loss counter must be stable before DB_VALID is asserted. The duration is measured in number of periods of the EQ feedback loop (specified by the EQ_FREQ bits) as indicated by Table 72. 373 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER TEST FEATURES DESCRIPTION :2 6: 12 50 AM PMC-1970624 20 07 01 Simultaneously asserting the CSB, RDB and WRB inputs causes all output pins and the data bus to be held in a high-impedance state. This test feature may be used for board testing. ug us t, Test mode registers are used to apply test vectors during production testing of the COMET. Test mode registers (as opposed to normal mode registers) are mapped into addresses 100H-1FFH. sd ay ,0 2A Test mode registers may also be used for board testing. When all of the constituent Telecom System Blocks within the COMET are placed in test mode 0, device inputs may be read and device outputs may be forced via the microprocessor interface (refer to the section "Test Mode 0" for details). Th ur Notes on Test Mode Register Bits: o on 1. Writing values into unused register bits has no effect. Reading unused bits can produce either a logic 1 or a logic 0; hence unused register bits should be masked off by software when read. Do wn l oa d ed by ab do u ra s ha d of bn ha cir 2. Writeable test mode register bits are not initialized upon reset unless otherwise noted. PROPRIETARY AND CONFIDENTIAL 374 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 X X Bit 5 W PMCATST X Bit 4 W PMCTST X Bit 3 W DBCTRL 0 Bit 2 R/W IOTST Bit 1 W HIZDATA Bit 0 R/W HIZIO 07 IDDQEN 20 W 2A Bit 6 :2 Unused 01 Default t, Bit 7 Function us Type ug Bit 6: Register 00BH: COMET Master Test 0 sd ay ,0 0 0 on Th ur This register is used to select COMET test features. All bits, except for PMCTST, PMCATST and IDDQEN, are reset to zero by a hardware reset of the COMET; a software reset of the COMET does not affect the state of the bits in this register. cir o IDDQEN: of bn ha The IDDQEN bit is used to configure the COMET for IDDQ tests. IDDQEN is cleared when CSB is high and RSTB is low or when IDDQEN is written as logic 0. When the IDDQEN bit is set to logic 1, the HIGHZ bit in the XLPG Line Driver Configuration register must also be set to logic 1. ha d PMCATST: ab do u ra s The PMCATST bit is used to configure the analog portion of the COMET for PMC's manufacturing tests. PMCATST is cleared when CSB is high and RSTB is low or when PMCATST is written as logic 0. PMCTST: oa d ed by The PMCTST bit is used to configure the COMET for PMC's manufacturing tests. When PMCTST is set to logic 1, the COMET microprocessor port becomes the test access port used to run the PMC manufacturing test vectors. The PMCTST bit is logically "ORed" with the IOTST bit, and is cleared by setting CSB high. Do wn l DBCTRL: The DBCTRL bit is used to pass control of the data bus drivers to the CSB pin. When the DBCTRL bit is set to logic 1, the CSB pin controls the output enable for the data bus. While the DBCTRL bit is set, holding the CSB pin PROPRIETARY AND CONFIDENTIAL 375 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 6: 50 high causes the COMET to drive the data bus and holding the CSB pin low tristates the data bus. The DBCTRL bit overrides the HIZDATA bit. The DBCTRL bit is used to measure the drive capability of the data bus driver pads. 07 IOTST: 2A ug us t, 20 The IOTST bit is used to allow normal microprocessor access to the test registers and control the test mode in each block in the COMET for board level testing. When IOTST is a logic 1, all blocks are held in test mode and the microprocessor may write to a block's test mode 0 registers to manipulate the outputs of the block and consequently the device outputs (refer to the "Test Mode 0 Details" in this section). ,0 HIZIO, HIZDATA: o Test Mode 0 cir 12.1 on Th ur sd ay The HIZIO and HIZDATA bits control the tri-state modes of the COMET . While the HIZIO bit is a logic 1, all output pins of the COMET except the data bus are held in a high-impedance state. The microprocessor interface is still active. While the HIZDATA bit is a logic 1, the data bus is also held in a highimpedance state which inhibits microprocessor read cycles. of bn ha In test mode 0, the COMET allows the logic levels on the device inputs to be read through the microprocessor interface, and allows the device outputs to be forced to either logic level through the microprocessor interface. ab do u ra s ha d To enable test mode 0, the IOTST bit in the Master Test Register (register 00BH) must be set to logic 1 and the following addresses must be written with 00H: 101H, 111H, 115H, 119H, 11DH, 121H, 125H, 129H, 131H, 139H, 141H, 149H, 14DH, 151H, 155H, 157H, 159H, 161H, 165H, 167H, 169H, 16BH, 16DH, 171H, 179H, 181H, 18DH, 191H, 1A9H, 1B1H, 1B9H, 1C1H, 1C9H, 1D1H, 1D7H, 1E1H, 1F1H and 1F9H. All other registers must be in their default (i.e., reset) state, except as noted below. ed by Reading the following address locations returns the values for the indicated inputs: oa d Table 73 Do wn l Addr - Observing Inputs in Test Mode 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 114H RCLKI1 118H TCLKI2 PROPRIETARY AND CONFIDENTIAL 376 Bit 1 Bit 0 RDAT1 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 BRFP 143H BTCLK BTFP BTPCM XCLK TRIMF 20 1F0H BTSIG 07 1D6H :2 6: BRCLK 01 134H 50 133H 100H RSYNC Bit 6 Bit 5 Bit 4 Bit 3 ,0 Bit 7 Bit 2 sd Addr 2A - Controlling Outputs in Test Mode 0 11AH BRPCM (OEB) BRSIG (OEB) on BRSIG cir INT4 143H Bit 0 TFP3 TDAT3 TCLKO3 BRFP BRFP (OEB) BRCLK BRCLK (OEB) BTCLK (OEB) BTCLK BTFP (OEB) BTFP o BRPCM Th ur 118H 133H Bit 1 ay Table 74 ug us t, Writing the following address locations forces the outputs to the value in the corresponding bit position: bn ha 144H d of Notes: ab do u ra s ha 1. To observe the value of RCLKI or RDAT, the RUNI bit in the Receive Line Interface Configuration register must be set to logic 1 and the RJATBYP bit in the Receive Options register must be set to logic 0. Additionally, the value on RDAT must be clocked in by RCLKI (one clock pulse) in order to be read. by 2. To observe the value of TCLKI, the PLLREF1 and PLLREF0 bits in the Transmit Timing Options register must both be set to logic 1. Do wn l oa d ed 3. To control the TFP, TDAT and TCLKO outputs, the TJATBYP bit in the Transmit Options register must be set to logic 0 and the TUNI bit in the Transmit Line Interface Configuration register must be set to logic 1. Additionally, the value written to the TDAT and TFP bits do not propagate to the TDAT and TFP outputs, respectively, until the TCLKO output is toggled twice (i.e., by setting the TCLKO bit to logic 0, logic 1, logic 0, logic 1 and back to logic 0). PROPRIETARY AND CONFIDENTIAL 377 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 4. Writing a logic 1 to the block interrupt signal INT at address 143H, asserts the INTB output low. In order to force INTB to the high impedance state, registers, 110H to 1FFH must be initialized to 00H. 07 01 5. The "signal_name (OEB)" signals will set the corresponding output signal, "signal_name", to high impedance when set high. ug JTAG Test Port 2A 12.2 us t, 20 6. The "signal_name (OEB)" signals will set the corresponding bidirectional signal, "signal_name", to an output when set low. Th ur sd ay ,0 The COMET JTAG Test Access Port (TAP) allows access to the TAP controller and the 4 TAP registers: instruction, bypass, device identification and boundary scan. Using the TAP, device input logic levels can be read, device outputs can be forced, the device can be identified and the device scan path can be bypassed. For more details on the JTAG port, please refer to the Operations section. on Instruction Register cir o Length - 3 bits Selected Register EXTEST Boundary Scan IDCODE Identification 001 SAMPLE Boundary Scan bn ha Instructions Instruction Codes, IR[2:0] 010 Bypass 011 Bypass 100 STCTEST Boundary Scan 101 BYPASS Bypass 110 BYPASS Bypass 111 BYPASS ed by ab do u BYPASS ra s ha d of 000 oa d Identification Register Do wn l Length - 32 bits Version number - 5H for Rev G and F, 4H for Rev E Part Number - 4351H PROPRIETARY AND CONFIDENTIAL 378 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 Manufacturer's identification code - 0CDH 01 :2 6: Device identification - 543510CDH for Rev. G and F, 443510CDH for Rev. E 07 - Boundary Scan Register 20 Table 75 Pin/ Enable Scan Register Bit HIZ 3,4 58 D1_OEB 1 XCLK 57 D2 TCLKI 56 TCLKO us Scan Register Bit Pin/ Enable Scan Register Bit 38 A7 18 37 A8 17 D2_OEB 1 36 ALE 16 55 D3 35 BRFP 15 TDAT 54 D3_OEB 1 34 BRFP_OEB 1 14 TFP 53 D4 33 BRSIG 13 BTCLK 52 D4_OEB 1 32 BRSIG_OEB 12 BTCLK_OEB 1 51 D5 31 BRPCM 11 BTPCM 50 D5_OEB 1 30 BRPCM_OEB 2 10 BTSIG 49 D6 29 BRCLK 9 BTFP 48 D6_OEB 1 28 BRCLK_OEB 1 8 2A ,0 ay sd ur Th on o cir ha bn of d ha 47 D7 27 RSYNC 7 CSB 46 D7_OEB 1 26 RCLKI 6 45 A0 25 RCLKI_OEB 1 5 44 A1 24 RDAT 4 WRB 43 A2 23 RDAT_OEB 1 3 INTB 42 A3 22 TRIMF 2 D0 41 A4 21 NC 1 DO_OEB 1 40 A5 20 NC_OEB 0 D1 39 A6 19 wn l oa d by RDB ab do u BTFP_OEB 1 ed ra s ug Pin/ Enable RSTB Do t, Length - 59 bits PROPRIETARY AND CONFIDENTIAL 379 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 Notes: 01 :2 1. These OEB signals, when set low, will set the corresponding bidirectional signal to an output. 20 07 2. These OEB signals, when set high, will set the corresponding output to high impedance. Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A 4. HIZ is the first bit in the boundary scan chain. ug us t, 3. When set high, TCLKO, TDAT, TFP, and RSYNC will be set to high impedance. PROPRIETARY AND CONFIDENTIAL 380 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 FUNCTIONAL TIMING 13.1 Transmit Backplane Interface 01 :2 6: 13 20 07 By convention, the first bit transmitted in each timeslot is designated bit 0; the last is bit 7. ug us t, Figure 13 - Transmit Backplane: CMS=0, FE=1, DE=1, BTFP is Input 2A BTCLK ,0 BTFP F-bit ay BTPCM ur sd Figure 14 - Transmit Backplane: CMS=0, FE=1, DE=0, BTFP is Input Th BTCLK on BTFP F-bit o BTPCM ha cir Figure 15 - Transmit Backplane: CMS=1, FE=1, DE=1, BTFP is Input bn BTCLK of BTFP F-bit ha d BTPCM ra s Figure 16 - Transmit Backplane: CMS=1, FE=0, DE=1, BTFP is Input ab do u BTCLK BTFP F-bit by BTPCM Do wn l oa d ed Figure 13, Figure 14, Figure 15, and Figure 16 above indicate the relationship between BTCLK, BTFP, and BTPCM with various settings for the BTIF's CMS, FE, and DE register bits in T1 mode with BTFP configured as an input (FPMODE=1). When FE and DE have the same value, the frame pulse is sampled on the same clock edge as the data. When FE and DE have opposite values, the frame pulse is sampled one clock edge before the data. In the above figures, the TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are logic zero. PROPRIETARY AND CONFIDENTIAL 381 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 01 :2 6: Figure 17 - Transmit Backplane: CMS=0, FE=1, DE=1, BTFP is Output 07 BTCLK BTPCM 20 BTFP t, F-bit 2 3 2A 1 ug us Figure 18 - Transmit Backplane: CMS=0, FE=1, DE=0, BTFP is Output ,0 BTCLK ay BTFP F-bit sd BTPCM ha cir o on Th ur Figure 17 and Figure 18 above indicate the relationship between BTCLK, BTFP, and BTPCM with two settings for the BTIF's CMS, FE, and DE register bits in T1 mode with BTFP configured as an output (FPMODE=0). When FE and DE have the same value, the frame pulse is updated on the same clock edge as the data is sampled. When FE and DE have opposite values, the frame pulse is updated three clock edge before the data is sampled. In the above figures, the TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are logic zero. - Transmit Backplane at 1.544 Mbit/s (T1 mode) of bn Figure 19 d BTFP ra s 7 0 ab do u BTPCM ha 1.544 M Hz BTCLK (CM S = 0) BTSIG D 1 X 2 3 4 5 6 7 A B C D Tim e Slot 23 F 0 1 2 X F-bit or parity 3 4 5 6 7 A B C D Tim e Slot 0 0 1 2 X 3 4 5 6 7 A B C D Tim e Slot 1 Do wn l oa d ed by A 1.544 Mbit/s backplane in T1 mode is configured by setting RATE[1:0] of the Transmit Backplane Configuration register to 'b00 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 19, BTFP, BTPCM and BTSIG are configured to be updated on the falling edge of BTCLK by setting FE and DE bits of the Transmit Backplane Configuration register to logic 0. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic 0, therefore BTFP is expected to be aligned to the first bit of the frame. A 1.544 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b00 and the E1/T1B bit of the PROPRIETARY AND CONFIDENTIAL 382 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 Global Configuration register to a logic 0. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. 20 07 01 :2 In Figure 19, BTPCM and BTFP are configured to be sampled on the falling edge of BTCLK by setting the DE and FE bits of the Transmit Backplane Configuration register to a logic 0. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BTFP is expected to be aligned to the F-bit position. - Transmit Backplane at 2.048 Mbit/s (T1 mode) us t, Figure 20 ug BTFP 2A 2.048 MHz BTCLK (CMS = 0) BTSIG D 0 1 2 3 X 4 5 6 7 A B C D F-bit X sd 7 ur BTPCM ay ,0 4.096 MHz BTCLK (CMS = 1) Th Time Slot 31 (used) X Time Slot 0 (unused) 0 1 2 X 3 4 5 6 7 0 A B C D X Time Slot 1 (used) bn ha cir o on A 2.048 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b01 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 20, BTFP, BTPCM and BTSIG are configured to be sampled on the rising edge of BTCLK by setting the FE and DE bits of the Transmit Backplane Configuration register to logic 1. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. ab do u ra s ha d of In Figure 20, the MAP bit of the Transmit Backplane Frame Pulse Configuration register is a logic 0. Therefore, every fourth time slot is unused, starting with timeslot 0. The framing bit is sampled during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. If MAP is logic 1, the 24 T1 channels would be aligned to the first 24 timeslots with the F-bit located in the last bit of the 32nd timeslot. Do wn l oa d ed by The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BTFP is expected to be aligned to the F-bit position. PROPRIETARY AND CONFIDENTIAL 383 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Transmit Backplane at 2.048 Mbit/s (E1 mode) 6: Figure 21 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 BTFP 07 2.048 M Hz BTCLK (CM S = 0) 7 BTSIG D 0 1 2 3 4 5 6 7 A B C D 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 A B C D 0 X X ug X us t, BTPCM 20 4.096 M Hz BTCLK (CM S = 1) Tim e Slot 31 Tim e Slot 0 Tim e Slot 1 Th ur sd ay ,0 2A A 2.048 Mbit/s backplane in E1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b01 and the E1/T1B bit of the Global Configuration register to a logic 1. In Figure 21, BTFP, BTPCM and BTSIG are configured to be sampled on the rising edge of BTCLK by setting the FE and DE bits of the Transmit Backplane Configuration register to logic 1. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. on The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BTFP is expected to be aligned to the first bit of the frame. cir o - Transmit Backplane at 4.096 Mbit/s (T1 mode) ha Figure 22 bn BTFP 4. 096 MHz BTCLK (CMS = 0) BTPCM TS 31 F of X X X TS 1 X A X X TS 2 TS 0 D X d C X X B C D X A B C D X ha BTSIG X oa d ed by ab do u ra s A 4.096 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b10 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 20, BTFP, BTPCM and BTSIG are configured to be sampled on the rising edge of BTCLK by setting the FE and DE bits of the Transmit Backplane Configuration register to logic 1. TSOFF[6:0] is set to 'b0000000 so that the first of the two interleaved bytes is sampled. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. Do wn l In Figure 20, the MAP bit of the Transmit Backplane Frame Pulse Configuration register is a logic 0. Therefore, every fourth time slot is unused, starting with timeslot 0. The framing bit is sampled during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. If MAP is logic 1, the 24 T1 channels would be aligned to the first 24 timeslots with the F-bit located in the last bit of the 32nd timeslot. PROPRIETARY AND CONFIDENTIAL 384 X PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 D TS 0 X X X X TS 1 X X A B C X D X TS 2 X A B C D X 20 C X 07 BTPCM TS 31 01 :2 BTFP 4. 096 MHz BTCLK (CMS = 0) BTSIG 50 - Transmit Backplane at 4.096 Mbit/s (E1 mode) 6: Figure 23 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 sd ay ,0 2A ug us t, A 4.096 Mbit/s backplane in E1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b10 and the E1/T1B bit of the Global Configuration register to a logic 1. In Figure 23, BTFP, BTPCM and BTSIG are configured to be sampled on the rising edge of BTCLK by setting the FE and DE bits of the Transmit Backplane Configuration register to logic 1. TSOFF[6:0] is set to 'b0000000 so that the first of the two interleaved bytes is sampled. - Transmit Backplane at 8.192 Mbit/s (T1 mode) Th ur Figure 24 on BTFP BTPCM X F X o 8. 192 MHz BTCLK (CMS = 0) X X X X X X X TS 1 X A B C D X X X X X X ha BTSIG X cir TS 0 ab do u ra s ha d of bn A 8.192 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b11 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 24, BTFP, BTPCM and BTSIG are configured to be sampled on the rising edge of BTCLK by setting the FE and DE bits of the Transmit Backplane Configuration register to logic 1. TSOFF[6:0] is set to 'b0000000 so that the first of the four interleaved bytes is sampled. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. Do wn l oa d ed by In Figure 24, the MAP bit of the Transmit Backplane Frame Pulse Configuration register is a logic 0. Therefore, every fourth time slot is unused, starting with timeslot 0. The framing bit is sampled during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. If MAP is logic 1, the 24 T1 channels would be aligned to the first 24 timeslots with the F-bit located in the last bit of the 32nd timeslot. PROPRIETARY AND CONFIDENTIAL 385 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Transmit Backplane at 8.192 Mbit/s (E1 mode) :2 6: Figure 25 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 BTFP 01 8. 192 MHz BTCLK (CMS = 0) TS 0 X X X BTSIG X X X X X TS 1 X X A B C D 07 X X X X X X 20 BTPCM ur - Concentration Highway Interface Timing, Example 1 1 2 3 4 5 6 7 8 9 10 11 12 o on BTC LK Th Figure 26 sd ay ,0 2A ug us t, A 8.192 Mbit/s backplane in E1 mode is configured by setting the RATE[1:0] bits of the Transmit Backplane Configuration register to 'b11 and the E1/T1B bit of the Global Configuration register to a logic 1. In Figure 25, BTFP, BTPCM and BTSIG are configured to be sampled on the rising edge of BTCLK by setting the FE and DE bits of the Transmit Backplane Configuration register to logic 1. TSOFF[6:0] is set to 'b0000000 so that the first of the four interleaved bytes is sampled. cir BTFP bit 6 TS 31 bit 7 TS 31 bit 1 TS 0 bit 0 TS 0 bit 2 TS 0 bit 3 TS 0 bit 4 TS 0 bit 5 TS 0 bit 6 TS 0 bit 7 TS 0 bit 0 TS 1 of bn bit 5 TS 31 ha CER = 4 BTPC M by ab do u ra s ha d CHI timing is configured by setting the BOFF_EN bit of the Transmit Backplane Bit Offset register to a logic 1. In Figure 26, the DE and FE register bits are set to logic 0 so that BTPCM, BTSIG and BTFP are sampled on the falling edge of BTCLK. CMS is set to logic 0 so that the clock rate is equal to the data rate. BOFF[2:0] is set to 'b000 so that the receive clock edge (CER) is equal to 4 (as determined by the table in the Transmit Backplane Bit Offset register description of BOFF[2:0]) and BTPCM is sampled 4 clock edges after BTFP is sampled. TSOFF is set to 'b0000000 so that there is no time slot offset. - Concentration Highway Interface Timing, Example 2 oa d ed Figure 27 1 2 3 4 5 6 7 8 9 10 11 12 wn l BTC LK Do BTFP BTPC M CER = 11 bit 5 TS 31 PROPRIETARY AND CONFIDENTIAL bit 6 TS 31 bit 7 TS 31 386 bit 0 TS 0 bit 1 TS 0 bit 2 TS 0 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 ug Receive Backplane Interface 2A 13.2 us t, 20 07 01 :2 6: 50 CHI timing is configured by setting the BOFF_EN bit of the Transmit Backplane Bit Offset register to a logic 1. In Figure 27, the FE register bit is set to logic 1 so that BTFP is sampled on the rising edge of BTCLK. The DE register bit is set to logic 0 so that BTPCM is sampled on the falling edge of BTCLK. CMS is set to logic 1 so that the clock rate is equal to two times the data rate. BOFF[2:0] is set to 'b001 so that the receive clock edge (CER) is equal to 11 (as determined by the table in the Transmit Backplane Bit Offset register description of BOFF[2:0]) and BTPCM is sampled 11 clock edges after BTFP is sampled. TSOFF is set to 'b0000000 so that there is no time slot offset. ay ,0 By convention, the first bit transmitted in each timeslot shall be designated bit 0; the last shall be bit 7. - Receive Backplane at 1.544 Mbit/s (T1 Mode) ur sd Figure 28 Th BRFP 7 BRSIG D 0 1 2 3 4 5 A B 6 7 F 0 1 2 3 4 5 6 7 A B C D 0 1 2 3 4 5 6 7 A B C D C ha X cir o BRPCM on 1.544 M Hz BRCLK (CM S = 0) X F-bit or parity Tim e Slot 0 X Tim e Slot 1 bn Tim e Slot 23 D Do wn l oa d ed by ab do u ra s ha d of A 1.544 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b00 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 28, BRFP, BRPCM and BRSIG are configured to be sampled on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BRFP is aligned to the first bit of the frame. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. PROPRIETARY AND CONFIDENTIAL 387 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Receive Backplane at 2.048 Mbit/s (T1 Mode) 6: Figure 29 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 BRFP 01 2.048 MHz BRCLK (CMS = 0) D 1 2 3 X 4 5 6 7 A B C D F X 0 X 2 Time Slot 0 (unused) 3 X 4 5 6 7 0 A B C D X Time Slot 1 (used) 2A Time Slot 31 (used) 1 t, BRSIG 0 us 7 ug BRPCM 20 07 4.096 MHz BRCLK (CMS = 1) Th ur sd ay ,0 A 2.048 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b01 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 29, BRFP, BRPCM and BRSIG are configured to be updated on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. bn ha cir o on In Figure 29, the MAP register bit is logic 0. As shown, every fourth time slot is unused, starting with the first. If MAP is a logic 1, time slots 0 through 23 would be used. The framing bit is presented during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BRFP is expected to be aligned to the first bit of the frame. - Receive Backplane at 2.048 Mbit/s (E1 Mode) ha d of Figure 30 ra s BRFP 2.048 MHz BRCLK (CMS = 0) ab do u 4.096 MHz BRCLK (CMS = 1) 7 BRSIG D 0 1 ed by BRPCM 2 X 3 4 5 6 7 A B C D 0 1 3 4 5 6 X Time Slot 31 Time Slot 0 7 0 1 2 3 4 5 6 7 0 A B C D X Time Slot 1 oa d A 2.048 Mbit/s backplane in E1 mode is configured by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b01 and E1/T1B bit of the Global Configuration register to logic 1. In Figure 30, BRFP, BRPCM and BRSIG are configured to be updated on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, wn l Do 2 PROPRIETARY AND CONFIDENTIAL 388 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 - Receive Backplane at 4.096 Mbit/s (T1 Mode) 07 01 Figure 31 6: 50 BRFP is expected to be aligned to the first bit of the frame. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. BRFP TS 30 TS 31 F X TS 0 B C X D A B C X D us A TS 1 X A B C D ug BRSIG t, BRPCM 20 4.096 MHz BRCLK (CMS = 0) Th ur sd ay ,0 2A A 4.096 Mbit/s backplane in T1 mode is configured by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b10 and the E1/T1B bit of the Global Configuration register to logic 0. In Figure 31, BRFP, BRPCM and BRSIG are configured to be updated on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. TSOFF[6:0] is set to 'b0000000 so that the first of the two interleaved bytes is sampled. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. bn ha cir o on In Figure 31, the MAP register bit is logic 0. As shown, every fourth time slot is unused, starting with the first. If MAP is a logic 1, time slots 0 through 23 would be used. The framing bit is presented during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BRFP is expected to be aligned to the first bit of the frame. - Receive Backplane at 4.096 Mbit/s (E1 Mode) d of Figure 32 ha BRFP BRPCM TS 30 A B C D ab do u BRSIG ra s 4. 096 MHz BRCLK (CMS = 0) TS 31 X A TS 0 B C X D TS 1 X A B C D Do wn l oa d ed by A 4.096 Mbit/s backplane in E1 mode is configured by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b10 and the E1/T1B bit of the Global Configuration register to logic 1. In Figure 32, BRFP, BRPCM and BRSIG are configured to be updated on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. TSOFF[6:0] is set to 'b0000000 so that the first of the two interleaved bytes is sampled. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. PROPRIETARY AND CONFIDENTIAL 389 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Receive Backplane at 8.192 Mbit/s (T1 Mode) 6: Figure 33 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 BRFP BRPCM TS 31 F 01 8. 192 MHz BRCLK (CMS = 0) X 07 TS 0 X X A B C D 20 BRSIG ay ,0 2A ug us t, A 8.192 Mbit/s backplane in T1 mode by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b11 and the E1/T1B bit of the Global Configuration register to a logic 0. In Figure 24, BRFP, BRPCM and BRSIG are configured to be updated on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. TSOFF[6:0] is set to 'b0000000 so that the first of the four interleaved bytes is sampled. Once the RATE[1:0] bits are set, a reset is required to change to a new RATE[1:0]. - Receive Backplane at 8.192 Mbit/s (E1 Mode) bn ha Figure 34 cir o on Th ur sd In Figure 24, the MAP register bit is logic 0. As shown, every fourth time slot is unused, starting with the first. If MAP is a logic 1, time slots 0 through 23 would be used. The framing bit is presented during bit 0 of time slot 0, so that only bits 1 to 7 of time slot 0 are ignored. The TSOFF[6:0], BOFF_EN and BOFF[2:0] register bits are all logic zero; therefore, BRFP is expected to be aligned to the first bit of the frame. BRFP BRPCM of 8. 192 MHz BRCLK (CMS = 0) A B C D X ra s X ha BRSIG TS 0 d TS 31 Do wn l oa d ed by ab do u A 8.192 Mbit/s backplane in E1 mode by setting the RATE[1:0] bits of the Receive Backplane Configuration register to 'b11 and the E1/T1B bit of the Global Configuration register to a logic 1. In Figure 34, BRFP, BRPCM and BRSIG are configured to be updated on the falling edge of BRCLK by setting the FE and DE bits of the Receive Backplane Configuration register to logic 0. TSOFF[6:0] is set to 'b0000000 so that the first of the four interleaved bytes is sampled. PROPRIETARY AND CONFIDENTIAL 390 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Concentration Highway Interface Timing, Example 1 1 2 3 4 5 6 7 8 9 10 11 6: Figure 35 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 12 01 :2 BRCLK 20 07 BRFP CER = 3 bit 6 TS 31 bit 7 TS 31 bit 1 TS 0 bit 0 TS 0 bit 2 TS 0 bit 3 TS 0 bit 4 TS 0 bit 5 TS 0 bit 6 TS 0 bit 7 TS 0 bit 0 TS 1 ug us bit 5 TS 31 t, BRPCM Th ur sd ay ,0 2A CHI timing is configured by setting the BOFF_EN bit of the Receive Backplane Configuration register to a logic 1. In Figure 35, FE is set to logic 0 so that BRFP is sampled on the falling edge of BRCLK. DE is set to logic 1 so that BRPCM is updated on the rising edge of BRCLK. CMS is set to logic 0 so that the clock rate is equal to the data rate. BOFF[2:0] is set to 'b000 so that the transmit clock edge (CET) is equal to 3 (as determined by the table in the register description of BOFF[2:0]) and BRPCM is updated 3 clock edges after BRFP is sampled. TSOFF is set to 'b0000000 so that there is no time slot offset. 1 2 3 4 5 6 7 8 9 10 11 12 bn ha BRCLK o on - Concentration Highway Interface Timing, Example 2 cir Figure 36 BRPCM Don't Care bit 6 TS 31 Don't Care CER = 8 bit 7 TS 31 Don't Care bit 0 TS 0 Don't Care bit 1 TS 0 Don't Care bit 2 TS 0 ra s ha bit 5 TS 31 d of BRFP Do wn l oa d ed by ab do u CHI timing is configured by setting BOFF_EN to a logic 1. In Figure 36, FE is set to logic 1 so that BRFP is sampled on the rising edge of BRCLK. DE is set to logic 1 so that BRPCM is updated on the rising edge of BRCLK. CMS is set to logic 1 so that the clock rate is equal to two times the data rate. BOFF[2:0] is set to 'b001 so that the transmit clock edge (CET) is equal to 8 (as determined by the table in the register description of BOFF[2:0]) and BRPCM is updated 8 clock edges after BRFP is updated. TSOFF is set to 'b0000000 so that there is no time slot offset. PROPRIETARY AND CONFIDENTIAL 391 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 OPERATION 14.1 Configuring the COMET from Reset 01 :2 6: 14 20 07 After a system reset (either via the RSTB pin or via the RESET register bit), the COMET will default to the following settings: us t, - Default Settings Receiver Section Framing Format T1 SF Line Code B8ZS Line interface Pins RXTIP and RXRING active short haul analog inputs TXTIP[1:0], TXRING[1:0], TCLKO, TDAT and TFP held low System Backplane * 1.544 Mbit/s data rate * 1.544 Mbit/s data rate on ur sd ay ,0 2A ug Setting Th Table 76 cir o * BRPCM, BRSIG high impedance bn ha * BRFP and BRCLK configured as inputs of Data Link ab do u ra s ha d Options oa d ed Diagnostics AMI * BTPCM active * BTSIG inactive * BTFP and BTCLK configured as inputs disabled * RX-ELST not bypassed * TX-ELST bypassed * PMON accumulates OOFs (not COFAs) * Signaling alignment disabled * F, CRC, FDL bit bypass disabled Not applicable Jitter attenuation enabled, with TCLKO referenced to BTCLK All diagnostic modes disabled All diagnostic modes disabled To configure the COMET for ESF framing format, after a reset, the following registers should be written with the indicated values: wn l Do T1 SF disabled by Timing Options Transmitter Section PROPRIETARY AND CONFIDENTIAL 392 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 - ESF Frame Format 50 Table 77 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Addr Data Effect Write CDRC Configuration Register 10H 00H Select B8ZS line code for receiver Write RX-ELST Configuration Register 1CH 00H Select 193-bit frame format. Write TX-ELST Configuration Register 20H 00H Select 193-bit frame format. Write T1 XBAS Configuration Register 54H 3XH Write T1 FRMR Configuration Register 48H Select B8ZS, enable for ESF in transmitter (bits defined by 'X' determine the FDL data rate & Zero Code suppression algorithm used) 1XH or Select ESF, 2 of 4 OOF threshold 5XH or Select ESF, 2 of 5 OOF threshold 9XH Select ESF, 2 of 6 OOF threshold ha cir o on Th ur sd ,0 2A ay ug us t, 20 07 01 :2 6: Action of bn (bits defined by 'X' determine the FDL data rate, should be same as those written to XBAS) 6AH ra s ha d Write RBOC Enable Register Enable 8 out of 10 validation Enable 4 out of 5 validation 60H 1XH Select ESF (bits defined by 'X' determine the ESF Yellow data rate, should be same as those written to T1 FRMR) Write IBCD Configuration Register 4CH 00H Enable Inband Code detection Write IBCD Activate Code Register 4EH 08H Program Loopback Activate Code pattern 4FH 44H Program Loopback Deactivate Code pattern oa d ed by ab do u Write ALMI Configuration Register wn l Do 00H or 02H Write IBCD Deactivate Code Register PROPRIETARY AND CONFIDENTIAL 393 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 Addr Data Effect Write SIGX Configuration Register 50H Select ESF 6: 01 04H 50 Action :2 PMC-1970624 20 07 To configure the COMET for SLC(R)96 framing format, after a reset, the following registers should be written with the indicated values: Write CDRC Configuration Register 10H 80H Write RX -ELST Configuration Register 1CH 00H Write TX-ELST Configuration Register 20H Write T1 XBAS Configuration Register 54H ay Select 193-bit frame format. 08H Select AMI, enable for SLC(R)96 in transmitter 08H or Select SLC(R)96, 2 of 4 OOF threshold 48H or Select SLC(R)96, 2 of 5 OOF threshold 88H Select SLC(R)96, 2 of 6 OOF threshold sd 00H bn of d 08H Select SLC(R)96 Write IBCD Configuration Register 4CH 00H Enable Inband Code detection Write IBCD Activate Code Register 4EH 08H Program Loopback Activate Code pattern ed ha 60H Write IBCD Deactivate Code Register 4FH 44H Program Loopback Deactivate Code pattern Write SIGX Configuration Register 50H 00H Select SLC(R)96 oa d by ab do u ra s Write ALMI Configuration Register wn l Do Select AMI line code for receiver Select 193-bit frame format. ur Th on o 48H ha cir Write T1 FRMR Configuration Register Effect ug Addr Data ,0 Action us t, - SLC(R)96 Frame Format 2A Table 78 To configure the COMET for SF framing format, after a reset, the following registers should be written with the indicated values: PROPRIETARY AND CONFIDENTIAL 394 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Addr Data Effect Write CDRC Configuration Register 10H 80H Select AMI line code for receiver Write RX-ELST Configuration Register 1CH 00H Select 193-bit frame format. Write TX-ELST Configuration Register 20H 00H Select 193-bit frame format. Write T1 XBAS Configuration Register 54H 00H Select AMI, enable for SF in transmitter Write T1 FRMR Configuration Register 48H 00H or Select SF, 2 of 4 OOF threshold 40H or Select SF, 2 of 5 OOF threshold 80H Select SF, 2 of 6 OOF threshold 00H Select SF 4CH 00H Enable Inband Code detection Write IBCD Activate Code Register 4EH 08H Program Loopback Activate Code pattern Write IBCD Deactivate Code Register 4FH 44H Program Loopback Deactivate Code pattern Write SIGX Configuration Register 50H 00H Select SF :2 01 07 20 t, us ug 2A ,0 ur on Th ab do u ra s ha d o of bn ha Write IBCD Configuration Register 60H cir Write ALMI Configuration Register 6: Action ay 50 - SF Frame Format sd Table 79 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 by To configure the COMET for T1DM framing format, after a reset, the following registers should be written with the indicated values: - T1DM Frame Format oa d ed Table 80 Do wn l Action Write CDRC Configuration Register PROPRIETARY AND CONFIDENTIAL Addr Data Effect 10H 80H Select AMI line code for receiver 395 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Addr Data Effect Write RX-ELST Configuration Register 1CH 00H Select 193-bit frame format. Write TX-ELST Configuration Register 20H 00H Select 193-bit frame format. Write T1 XBAS Configuration Register 54H 04H or 0CH Select AMI, enable for T1DM in transmitter Write T1 FRMR Configuration Register 48H 04H Select T1DM, 4 of 12 OOF threshold Write ALMI Configuration Register 60H 04H or 6: :2 01 07 20 t, us ug 2A Select T1DM with standard Red integration ,0 ay 4CH on Th Write IBCD Configuration Register ur sd 0CH cir o 4EH Select T1DM with alternate Red integration 00H Enable Inband Code detection 08H Program Loopback Activate Code pattern 4FH 44H Program Loopback Deactivate Code pattern Write SIGX Configuration Register 50H 00H Select T1DM Addr Data Effect Write Global Configuration Register 00H 01H Select E1 mode. Write RXCE Receive Data Link 1 Control Register 028H 00H Disable extraction of T1 data link for HDLC receiver #1. Write TXCI Transmit Data Link 1 Control Register 038H 00H Disable insertion of T1 data link from HDLC transmitter #1. Write E1 TRAN Configuration Register 80H 70H Enable CRC multiframe generation Write E1 FRMR Frame Alignment Options Register 90H 80H Enable CRC multiframe search algorithm Do ha wn l oa d by ab do u Action - E1 Frame Format ra s Table 81 d of bn ha Write IBCD Deactivate Code Register ed Write IBCD Activate Code Register 50 Action PROPRIETARY AND CONFIDENTIAL 396 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 - PMON Polling Sequence 01 Table 82 6: 50 To access the Performance Monitor Registers, the following polling sequence should be used: Addr Offset Data Effect Write PMON Framing Bit Error Count Register 59H 00H Latch performance data into PMON registers Read Framing Bit Error Count 59H Read OOF/COFA/FEBE (LSB) Count Register 5AH Read OOF/COFA/FEBE (MSB) Count Register 5BH 20 t, us 2A ug Read Framing bit error count ,0 ay sd ur Th on o cir ha bn Read least significant byte outof-frame event count, change of frame alignment event count if CCOFA bit in COMET Receive Options Register is set, or FEBE if E1 Read most significant byte outof-frame event count, change of frame alignment event count if CCOFA bit in COMET Receive Options Register is set, or FEBE if E1 5CH Read least significant byte of bit error event or CRC error count 5DH Read most significant byte of bit error event or CRC error count Read LCV Count (LSB) Register 5EH Read least significant byte of line code violation count Read LCV Count (MSB) Register 5FH Read most significant byte of line code violation count ha d of Read BEE/CRCE Count (LSB) Register 07 Action ed by ab do u ra s Read BEE/CRCE Count (MSB) Register Do wn l oa d To configure the COMET to utilize the internal HDLC transmitter and receiver for processing the ESF facility data link, the following registers should be written with the indicated values: PROPRIETARY AND CONFIDENTIAL 397 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 - ESF FDL Processing 50 Table 83 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Addr Data Effect Write RXCE Receive Data Link 1 Control Register 028H 20H Select extraction of ESF Facility Data Link for HDLC receiver #1. (COMET must be set up for ESF frame format.) Write TXCI Transmit Data Link 1 Control Register 038H 20H Select insertion of ESF Facility Data Link from HDLC transmitter #1. (COMET must be set up for ESF frame format.) ay Using the Internal HDLC Transmitters sd 14.2 ,0 2A ug us t, 20 07 01 :2 6: Action on Th ur It is important to note that the access rate to the TDPR registers is limited by the rate of the transmit clock. The TDPR registers should be accessed at a rate no faster than that of the transmit system clock. of bn ha cir o To properly initialize the transmit HDLC controllers in transmit basic frame alignment mode (FPTYP is logic 0), transmit multiframe alignment (FPTYP is logic 1) must be configured for at least one multiframe (i.e., for at least one multiframe period in frame pulse master mode or for at least one input frame pulse in frame pulse slave mode). After this initialization, the FPTYP can be set to any desired value. ab do u ra s ha d Upon reset, the TDPR should be disabled by setting the EN bit in the TDPR Configuration Register to logic 0 (default value). After making all initial configurations to the TDPR, the EN bit should be set to logic 1 to enable the TDPR and then the FIFOCLR bit should be set and then cleared to initialize the TDPR FIFO. The TDPR is now ready to transmit. Do wn l oa d ed by To initialize the TDPR, the TDPR Configuration Register must be properly set. If FCS generation is desired, the CRC bit should be set to logic 1. If the block is to be used in interrupt driven mode, then interrupts should be enabled by setting the FULLE, OVRE, UDRE, and LFILLE bits in the TDPR Interrupt Enable register to logic 1. The TDPR operating parameters in the TDPR Upper Transmit Threshold and TDPR Lower Interrupt Threshold registers should be set to the desired values. The TDPR Upper Transmit Threshold sets the value at which the TDPR automatically begins the transmission of HDLC packets, even if no complete packets are in the FIFO. Transmission will continue until the current packet is transmitted and the number of bytes in the TDPR FIFO falls to, or below, this threshold level. The TDPR will always transmit all complete HDLC packets PROPRIETARY AND CONFIDENTIAL 398 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 (packets with EOM attached) in its FIFO. Finally, the TDPR can be enabled by setting the EN bit to logic 1. If no message is sent after the EN bit is set to logic 1, continuous flags will be sent. ug us t, 20 07 01 The TDPR can be used in a polled or interrupt driven mode for the transfer of packet data. In the polled mode the processor controlling the TDPR must periodically read the TDPR Interrupt Status register to determine when to write to the TDPR Transmit Data register. In the interrupt driven mode, the processor controlling the TDPR uses the INTB output to identify the interrupts which determine when writes can or must be done to the TDPR Transmit Data register. 2A 14.2.1 Automatic transmission mode using interrupts: ha cir o on Th ur sd ay ,0 The TDPR automatically transmits a packet once it is completely written into the TDPR FIFO. The TDPR also begins transmission of bytes once the FIFO level exceeds the programmable Upper Transmit Threshold. The CRC bit can be set to logic 1 so that the FCS is generated and inserted at the end of a packet. The TDPR Lower Interrupt Threshold should be set to such a value that sufficient warning of an underrun is given. The FULLE, LFILLE, OVRE, and UDRE bits are all set to logic 1 so an interrupt on INTB is generated upon detection of a FIFO full state, a FIFO depth below the lower limit threshold, a FIFO overrun, or a FIFO underrun. The following procedure should be followed to transmit HDLC packets: of bn 1. Wait for data to be transmitted. Once data is available to be transmitted, go to step 2. ha d 2. Write the data byte to the TDPR Transmit Data register. ra s 3. If all bytes in the packet have been sent, set the EOM bit in the TDPR Configuration register to logic 1. Go to step 1. ab do u 4. If there are more bytes in the packet to be sent, go to step 2. ed by While performing steps 1 to 4, the processor should monitor for interrupts generated by the TDPR. When an interrupt is detected, the TDPR Interrupt Routine should be executed. Do wn l oa d The TDPR will force transmission of the packet information when the FIFO depth exceeds the threshold programmed with the UTHR[6:0] bits in the TDPR Upper Transmit Threshold register. Transmission will not stop until the last byte of all complete packets is transmitted and the FIFO depth is at or below the threshold limit. The user should watch the FULLI and LFILLI interrupts to prevent overruns and underruns. PROPRIETARY AND CONFIDENTIAL 399 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 14.2.2 TDPR Interrupt Routine: 01 :2 The following procedure should be carried out when an interrupt is detected on INT: 20 07 1. Read the TDPR Interrupt Status register. ,0 2A ug us t, 2. If UDRI=1, then the FIFO has underrun and the last packet transmitted has been corrupted and needs to be retransmitted. When the UDRI bit transitions to logic 1, one Abort sequence and continuous flags will be transmitted. The TDPR FIFO is held in reset state. To re-enable the TDPR FIFO and to clear the underrun, the TDPR Interrupt Status/UDR Clear register should be written with any value. on Th ur sd ay 3. If OVRI=1, then the FIFO has overflowed. The packet which the last byte written into the FIFO belongs to has been corrupted and must be retransmitted. Other packets in the FIFO are not affected. Either a timer can be used to determine when sufficient bytes are available in the FIFO or the user can wait until the LFILLI interrupt is set, indicating that the FIFO depth is at the lower threshold limit. of bn ha cir o If the FIFO overflows on the packet currently being transmitted (packet is greater than 128 bytes long), an Abort signal is scheduled to be transmitted, the FIFO is emptied, and then flags are continuously sent until there is data to be transmitted. The FIFO is held in reset until a write to the TDPR Transmit Data register occurs. This write contains the first byte of the next packet to be transmitted. ed by ab do u ra s ha d 4. If OVRI=1, then the FIFO has overflowed. The packet which the last byte written into the FIFO belongs to has been corrupted and must be retransmitted. Other packets in the FIFO are not affected. When an overflow occurs, the OVR output signal is set. Either a timer can be used to determine when sufficient bytes are available in the FIFO or the user can wait until the LFILLI interrupt is set, indicating that the FIFO depth is at the lower threshold limit. The OVR output signal remains set until the next write to the TDPR Transmit Data register. This write contains the first byte of the next packet to be transmitted. Do wn l oa d If the FIFO overflows on the packet currently being transmitted (packet is greater than 128 bytes long), the OVR output signal is set, an Abort signal is scheduled to be transmitted, the FIFO is emptied, and then flags are continuously sent until there is data to be transmitted. The FIFO is held in reset until a write to the TDPR Transmit Data register occurs. This write contains the first byte of the next packet to be transmitted. PROPRIETARY AND CONFIDENTIAL 400 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 6: 50 5. If FULLI=1 and FULL=1, then the TDPR FIFO is full and no further bytes can be written. When in this state, either a timer can be used to determine when sufficient bytes are available in the FIFO or the user can wait until the LFILLI interrupt is set, indicating that the FIFO depth is at the lower threshold limit. t, 20 07 If FULLI=1 and FULL=0, then the TDPR FIFO had reached the FULL state earlier, but has since emptied out some of its data bytes and now has space available in its FIFO for more data. ay ,0 2A ug us 6. If LFILLI=1 and BLFILL=1, then the TDPR FIFO depth is below its lower threshold limit. If there is more data to transmit, then it should be written to the TDPR Transmit Data register before an underrun occurs. If there is no more data to transmit, then an EOM should be set at the end of the last packet byte. Flags will then be transmitted once the last packet has been transmitted. Th ur sd If LFILLI=1 and BLFILL=0, then the TDPR FIFO had fallen below the lowerthreshold state earlier, but has since been refilled to a level above the lowerthreshold level. o on 14.2.3 Automatic transmission mode using polling: ab do u ra s ha d of bn ha cir The TDPR automatically transmits a packet once it is completely written into the TDPR FIFO. The TDPR also begins transmission of bytes once the FIFO level exceeds the programmable Upper Transmit Threshold. The CRC bit can be set to logic 1 so that the FCS is generated and inserted at the end of a packet. The TDPR Lower Interrupt Threshold should be set to such a value that sufficient warning of an underrun is given. The FULLE, LFILLE, OVRE, and UDRE bits are all set to logic 0 since packet transmission is set to work with a periodic polling procedure. The following procedure should be followed to transmit HDLC packets: 1. Wait until data is available to be transmitted, then go to step 2. by 2. Read the TDPR Interrupt Status register. Do wn l oa d ed 3. If FULL=1, the TDPR FIFO is full and no further bytes can be written. Continue polling the TDPR Interrupt Status register until either FULL=0 or BLFILL=1. Then, go to either step 4 or 5 depending on implementation preference. 4. If BLFILL=1, the TDPR FIFO depth is below its lower threshold limit. Write the data into the TDPR Transmit Data register. Go to step 6. PROPRIETARY AND CONFIDENTIAL 401 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 5. If FULL=0, the TDPR FIFO has room for at least 1 more byte to be written. Write the data into the TDPR Transmit Data register. Go to step 6. 01 :2 6. If more data bytes are to be transmitted in the packet, go to step 2. 7 6 5 4 3 2 1 0 1 1 1 1 1 1 0 FLAG ,0 Address (high) data bytes written to the Transmit Data Register and serially transmitted, bit 1 first cir o on Th ur sd ay (low) CONTROL ug BIT: 8 us t, - Typical Data Frame 2A Figure 37 20 07 7. If all bytes in the packet have been sent, set the EOM bit in the TDPR Configuration register to logic 1. Go to step 1. ha Frame Check appended after EOM is set, if CRC is set bn Sequence 1 1 of 1 1 1 1 0 FLAG ra s Using the Internal HDLC Receivers ab do u 14.3 ha d 0 oa d ed by On power up of the system, the RDLC should be disabled by setting the EN bit in the Configuration Register to logic 0. The Interrupt Control Register should then be initialized to enable the INTB output and to select the FIFO buffer fill level at which an interrupt will be generated. If the INTE bit is not set to logic 1, the Status Register must be continuously polled to check the interrupt status (INTR) bit. Do wn l After the Interrupt Control Register has been written, the RDLC can be enabled at any time by setting the EN bit in the Configuration Register to logic 1. When the RDLC is enabled, it will assume the link status is idle (all ones) and immediately begin searching for flags. When the first flag is found, an interrupt will be generated, and a dummy byte will be written into the FIFO buffer. This is done to provide alignment of link up status with the data read from the FIFO. PROPRIETARY AND CONFIDENTIAL 402 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 20 07 01 :2 6: 50 When an abort character is received, another dummy byte and link down status is written into the FIFO. This is done to provide alignment of link down status with the data read from the FIFO. It is up to the controlling processor to check the COLS Status Register bit for a change in the link status. If the COLS Status Register bit is set to logic 1, the FIFO must be emptied to determine the current link status. The first flag and abort status encoded in the PBS bits is used to set and clear a Link Active software flag. sd ay ,0 2A ug us t, When the last byte of a properly terminated packet is received, an interrupt is generated. When the Status Register is read the PKIN bit will be logic 1. This can be a signal to the external processor to empty the bytes remaining in the FIFO or to just increment a number-of-packets-received count and wait for the FIFO to fill to a programmable level. Once the Status Register is read, the PKIN bit is cleared to logic 0 . If the Status Register is read immediately after the last packet byte is read from the FIFO, the PBS[2] bit will be logic 1 and the CRC and non-integer byte status can be checked by reading the PBS[1:0] bits. Th ur When the FIFO fill level is exceeded, an interrupt is generated. The FIFO must be emptied to remove this source of interrupt. bn ha cir o on The RDLC can be used in a polled or interrupt driven, or DMA-controlled mode for the transfer of frame data. In the polled mode, the INTB output is not used, and the processor controlling the RDLC must periodically read the Status Register of the RDLC to determine when to read the Data Register. In the interrupt driven mode, the processor controlling the RDLC uses the INTB output to determine when to read the Data Register. ra s ha d of In the case of interrupt driven data transfer from the RDLC to the processor, the INTB output of the RDLC is connected to the interrupt input of the processor. Once the processor has determined the RDLC is the source of the interrupt, the interrupt service routine should process the data in the following order: ab do u 1. RDLC Status Register Read. If INTR=1 then proceed to step 2 else find the interrupt source elsewhere. ed by 2. If OVR = 1, discard last frame and go to step 1. Overrun causes a reset of FIFO pointers. Any packets that may have been in the FIFO are lost. oa d 3. If COLS = 1, set the EMPTY FIFO software flag. Do wn l 4. If PKIN = 1, increment the PACKET COUNT. If the FIFO is desired to be emptied as soon as a complete packet is received, set the EMPTY FIFO software flag. If the EMPTY FIFO software flag is not set, FIFO emptying will be delayed until the FIFO fill level is exceeded. PROPRIETARY AND CONFIDENTIAL 403 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 5. Data Register Read. :2 6: 6. Status Register Read. 07 01 7. If OVR = 1, discard last frame and go to step 1. Overrun causes a reset of FIFO pointers. Any packets that may have been in the FIFO are lost. 20 8. If COLS = 1, set the EMPTY FIFO software flag. 2A ug us t, 9. If PKIN = 1, increment the PACKET COUNT. If the FIFO is desired to be emptied as soon as a complete packet is received, set the EMPTY FIFO software flag. If the EMPTY FIFO software flag is not set, FIFO emptying will be delayed until the FIFO fill level is exceeded. sd ay ,0 10. Start the processing of FIFO data. Use the PBS[2:0] packet byte status bits to decide what is to be done with the FIFO data. Th ur a) If PBS[2:0] = 001, discard data byte read in step 5 and set the LINK ACTIVE software flag. o on b) If PBS[2:0] = 010, discard the data byte read in step 5 and clear the LINK ACTIVE software flag. bn ha cir c) If PBS[2:0] = 1XX, store the last byte of the packet, decrement the PACKET COUNT, and check the PBS[1:0] bits for CRC or NVB errors before deciding whether or not to keep the packet. of d) If PBS[2:0] = 000, store the packet data. ra s ha d 11. If FE = 0 and INTR = 1 or FE = 0 and EMPTY FIFO = 1, go to step 5 else clear the EMPTY FIFO software flag and leave this interrupt service routine to wait for the next interrupt. by ab do u The link state is typically a local software variable. The link state is inactive if the RDLC is receiving all ones or receiving bit-oriented codes which contain a sequence of eight ones. The link state is active if the RDLC is receiving flags or data. wn l oa d ed If the RDLC data transfer is operating in the polled mode, processor operation is exactly as shown above for the interrupt driven mode, except that the entry to the service routine is from a timer, rather than an interrupt. T1 Automatic Performance Report Format Do 14.4 PROPRIETARY AND CONFIDENTIAL 404 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER Bit 7 Bit 6 Bit 5 1 Bit 4 FLAG SAPI 07 2 Bit 3 :2 Bit 8 Bit 2 Bit 1 C/R EA 01 Octet No. 6: - Performance Report Message Structure and Contents 3 TEI 4 CONTROL EA G3 LV G4 U1 U2 G5 SL G6 6 FE SE LB G1 R G2 Nm NI 7 G3 LV G4 U1 U2 G5 SL G6 8 FE SE LB ay G1 R G2 Nm NI 9 G3 LV G4 U1 U2 G5 SL G6 10 FE SE LB G1 R G2 Nm NI 11 G3 LV G4 U1 U2 G5 SL G6 12 FE SE LB G1 R G2 Nm NI o on Th ur ,0 2A ug 5 sd us t, 20 Table 84 50 AM PMC-1970624 FCS cir 13 FCS ha 14 FLAG of bn 15 ha d Notes: Octet Contents Interpretation 1 01111110 Opening LAPD Flag 00111000 From CI: oa d 00111010 From carrier: SAPI=14,C/R=1,EA=0 3 00000001 TEI=0,EA=1 4 00000011 Unacknowledged Frame 5,6 Variable Data for latest second (T') wn l ed by Octet No. 2 Do - Performance Report Message Structure Notes ab do u Table 85 ra s 1. The order of transmission of the bits is LSB (Bit 1) to MSB (Bit 8). PROPRIETARY AND CONFIDENTIAL 405 SAPI=14, C/R=0, EA=0 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Octet Contents Interpretation 7,8 Variable Data for Previous Second(T'-1) 9,10 Variable Data for earlier Second(T'-2) 11,12 Variable Data for earlier Second(T'-3) 13,14 Variable CRC16 Frame Check Sequence 15 01111110 Closing LAPD flag 6: :2 01 07 20 t, us ug - Performance Report Message Contents 2A Table 86 50 Octet No. Interpretation G1=1 CRC ERROR EVENT =1 G2=1 1 427 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER <23 - 16 Bits of Data> WRITE DAH <15 - 8 Bits of Data> WRITE DBH <7 - 0 Bits of Data> :2 01 20 us 00D 01D 02D 03D 04D 05D 06D 07D 08D 09D 10D 11D 12D 13D 14D 15D 16D 17D 18D 19D 03 FE 18 40H 03 F6 18 40H 03 EE 18 40H 03 E6 18 40H 03 DE 18 40h 03 D6 18 40H 03 D6 18 40H 03 D6 18 40H 03 CE 18 40H 03 CE 18 40H 03 CE 18 40H 03 CE 18 40H 03 C6 18 40H 03 C6 18 40H 03 C6 18 40H 0B BE 18 40H 0B BE 18 40H 0B BE 18 40H 0B BE 18 40H 0B B6 18 40H on o cir ha bn of d ha ra s ab do u by ed oa d wn l Do RAM Address sd Content (MSB..LSB) Th RAM Address ay - RLPS Equalizer RAM Table (T1 mode) ur Table 107 ,0 2A ug PAUSE
t, WRITE FCH 6: WRITE D9H AM ISSUE 11 50 PMC-1970624 PROPRIETARY AND CONFIDENTIAL 428 128D 129D 130D 131D 132D 133D 134D 135D 136D 137D 138D 139D 140D 141D 142D 143D 144D 145D 146D 147D Content (MSB..LSB) 97 5E 7A C0H 97 5E 7A C0H 97 5E 7A C0H 9F 5E 8A C0H 9F 5E 8A C0H 9F 5E 8A C0H 9F 5E 8A C0H 9F 5E 8A C0H A7 56 9A C0H A7 56 9A C0H A7 56 9A C0H A7 56 9A C0H A7 56 AA C0H A7 56 AA C0H A7 56 AA C0H AF 4E AA C0H AF 4E AA C0H AF 4E AA C0H AF 4E AA C0H AF 4E AA C0H PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 20D 21D 22D 23D 24D 25D 26D 27D 28D 29D 30D 31D 32D 33D 34D 35D 36D 37D 38D 39D 40D 41D 42D 43D 44D 45D 46D 47D 48D 49D 50D 0B B6 18 40H 0B B6 18 40H 0B B6 18 40H 13 AE 18 38H 13 AE 18 3CH 13 AE 18 40H 13 AE 18 40H 13 AE 18 40H 13 AE 18 40H 1B B6 18 B8H 1B AE 18 B8H 1B AE 18 BCH 1B AE 18 C0H 1B AE 18 C0H 23 A6 18 C0H 23 A6 18 C0H 23 A6 18 C0H 23 A6 18 C0H 23 A6 18 C0H 23 9E 18 C0H 23 9E 18 C0H 23 9E 18 C0H 23 9E 18 C0H 23 9E 18 C0H 2B 96 18 C0H 2B 96 18 C0H 2B 96 18 C0H 33 96 19 40H 37 96 19 40H 37 96 19 40H 37 96 19 40H 148D 149D 150D 151D 152D 153D 154D 155D 156D 157D 158D 159D 160D 161D 162D 163D 164D 165D 166D 167D 168D 169D 170D 171D 172D 173D 174D 175D 176D 177D 178D B7 46 AA C0H B7 46 AA C0H B7 46 AA C0H B7 46 AA C0H B7 46 AA C0H B7 46 AA C0H B7 46 AA C0H B7 46 BA C0H B7 46 BA C0H B7 46 BA C0H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BF 4E BB 40H BE 46 CB 40H BE 46 CB 40H BE 46 CB 40H BE 46 CB 40H BE 46 CB 40H BE 46 CB 40H BE 46 DB 40H BE 46 DB 40H BE 46 DB 40H C6 3E CB 40H C6 3E CB 40H C6 3E DB 40H 429 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s ab do u by ed PROPRIETARY AND CONFIDENTIAL 50 RAM Address oa d wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 51D 52D 53D 54D 55D 56D 57D 58D 59D 60D 61D 62D 63D 64D 65D 66D 67D 68D 69D 70D 71D 72D 73D 74D 75D 76D 77D 78D 79D 80D 81D 3F 9E 19 C0H 3F 9E 19 C0H 3F 9E 19 C0H 3F A6 1A 40H 3F A6 1A 40H 3F A6 1A 40H 3F A6 1A 40H 3F 96 19 C0H 3F 96 19 C0H 3F 96 19 C0H 3F 96 19 C0H 47 9E 1A 40H 47 9E 1A 40H 47 9E 1A 40H 47 96 1A 40H 47 96 1A 40H 47 96 1A 40H 47 96 1A 40H 4F 8E 1A 40H 4F 8E 1A 40H 4F 8E 1A 40H 4F 8E 1A 40H 4F 8E 1A 40H 57 86 1A 40H 57 86 1A 40H 57 86 1A 40H 57 86 1A 40H 57 86 1A 40H 5F 86 1A C0H 5F 86 1A C0H 5F 86 1A C0H 179D 180D 181D 182D 183D 184D 185D 186D 187D 188D 189D 190D 191D 192D 193D 194D 195D 196D 197D 198D 199D 200D 201D 202D 203D 204D 205D 206D 207D 208D 209D C6 3E DB 40H C6 3E DB 40H C6 44 DB 40H C6 44 DB 40H C6 44 DB 40H C6 44 DB 40H C6 3C DB 40H C6 3C DB 40H C6 3C DB 40H C6 3C DB 40H D6 34 DB 40H D6 34 DB 40H D6 34 DB 40H D6 34 DB 40H D6 34 DB 40H DE 2C DB 3CH DE 2C DB 3CH DE 2C DB 3CH E6 2C DB 40H E6 2C DB 40H E6 2C DB 40H E6 2C DB 40H E6 2C DB 40H E6 2C EB 40H E6 2C EB 40H E6 2C EB 40H EE 2C FB 40H EE 2C FB 40H EE 2C FB 40H EE 2D 0B 40H EE 2D 0B 40H 430 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s ab do u by ed PROPRIETARY AND CONFIDENTIAL 50 RAM Address oa d wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 82D 83D 84D 85D 86D 87D 88D 89D 90D 91D 92D 93D 94D 95D 96D 97D 98D 99D 100D 101D 102D 103D 104D 105D 106D 107D 108D 109D 110D 111D 112D 5F 86 1A C0H 5F 86 1A C0H 5F 86 1A C0H 5F 7E 1A C0H 5F 7E 1A C0H 5F 7E 1A C0H 5F 7E 1A C0H 5F 7E 1A C0H 67 7E 2A C0H 67 7E 2A C0H 67 7E 2A C0H 67 7E 2A C0H 67 76 2A C0H 67 76 2A C0H 67 76 2A C0H 67 76 2A C0H 67 76 2A C0H 6F 6E 2A C0H 6F 6E 2A C0H 6F 6E 2A C0H 6F 6E 2A C0H 77 6E 3A C0H 77 6E 3A C0H 77 6E 3A C0H 77 6E 3A C0H 7F 66 3A C0H 7F 66 3A C0H 7F 66 4A C0H 7F 66 4A C0H 7F 66 4A C0H 7F 66 4A C0H 210D 211D 212D 213D 214D 215D 216D 217D 218D 219D 220D 221D 222D 223D 224D 225D 226D 227D 228D 229D 230D 231D 232D 233D 234D 235D 236D 237D 238D 239D 240D EE 2D 0B 40H EE 2D 0B 40H EE 2D 0B 40H F5 25 0B 38H F5 25 0B 3CH F5 25 0B 40H F5 25 1B 40H F5 25 1B 40H F5 25 1B 40H F5 25 1B 40H F5 25 1B 40H FD 25 2B 40H FD 25 2B 40H FD 25 2B 40H FD 25 2B 40H FD 25 27 40H FD 25 27 40H FD 25 27 40H FD 25 23 40H FD 25 23 40H FD 25 23 40H FD 25 33 40H FD 25 33 40H FD 25 33 40H FD 25 33 40H FD 25 33 40H FD 25 33 40H FC 25 33 40H FC 25 33 40H FC 25 43 40H FC 25 43 40H 431 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s ab do u by ed PROPRIETARY AND CONFIDENTIAL 50 RAM Address oa d wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 113D 114D 115D 116D 117D 118D 119D 120D 121D 122D 123D 124D 125D 126D 127D 87 66 5A C0H 87 66 5A C0H 87 66 5A C0H 87 66 5A C0H 87 66 5A C0H 87 5E 5A C0H 87 5E 5A C0H 87 5E 5A C0H 87 5E 5A C0H 87 5E 5A C0H 8F 5E 6A C0H 8F 5E 6A C0H 8F 5E 6A C0H 8F 5E 6A C0H 97 5E 7A C0H 241D 242D 243D 244D 245D 246D 247D 248D 249D 250D 251D 252D 253D 254D 255D FC 25 43 40H FC 25 43 44H FC 25 43 48H FC 25 43 4CH FC 25 43 BCH FC 25 43 C0H FC 25 43 C0H FC 23 43 C0H FC 23 43 C0H FC 23 43 C0H FC 21 43 C0H FC 21 43 C0H FC 21 53 C0H FC 21 53 C0H FC 21 53 C0H 6: :2 01 07 20 t, us ug 2A ,0 ay sd RAM Address Content (MSB..LSB) 07 DE 18 2CH 07 DE 18 2CH 07 D6 18 2CH 07 D6 18 2CH 07 D6 18 2CH 07 CE 18 2CH 07 CE 18 2CH 07 CE 18 2CH 07 C6 18 2CH 07 C6 18 2CH 07 C6 18 2CH 07 BE 18 2CH 07 BE 18 2CH 128D 129D 130D 131D 132D 133D 134D 135D 136D 137D 138D 139D 140D 97 4E AF 2CH 97 4E AF 2CH 97 4E AB 2CH 97 4E AB 2CH 97 4E AB 2CH 9F 4E AB 2CH 9F 4E BB 2CH 9F 4E BB 2CH 9F 4E BB 2CH 9F 4E CB 2CH A7 4E CB 2CH A7 4E CB 2CH A7 46 CB 2CH of Content (MSB..LSB) d ha ra s ab do u by ed oa d wn l ur Th on o cir bn ha - RLPS Equalizer RAM Table (E1 mode) RAM Address 00D 01D 02D 03D 04D 05D 06D 07D 08D 09D 10D 11D 12D 50 RAM Address Table 108 Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PROPRIETARY AND CONFIDENTIAL 432 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 13D 14D 15D 16D 17D 18D 19D 20D 21D 22D 23D 24D 25D 26D 27D 28D 29D 30D 31D 32D 33D 34D 35D 36D 37D 38D 39D 40D 41D 42D 43D 07 BE 18 2CH 07 BE 18 2CH 07 BE 18 2CH 07 B6 18 2CH 07 B6 18 2CH 07 B6 18 2CH 07 B6 18 2CH 07 B6 18 2CH 07 AE 18 2CH 07 AE 18 2CH 07 AE 18 2CH 07 AE 18 2CH 07 AE 18 2CH 07 B6 18 ACH 07 AE 18 ACH 07 AE 18 ACH 07 AE 18 ACH 07 AE 18 ACH 07 A6 18 ACH 07 A6 18 ACH 07 A6 18 ACH 07 A6 18 ACH 07 9E 18 ACH 07 A6 19 2CH 07 A6 19 2CH 07 A6 19 2CH 0F A6 19 2CH 0F A6 19 2CH 0F 9E 19 2CH 0F 9E 19 2CH 0F 9E 19 2CH 141D 142D 143D 144D 145D 146D 147D 148D 149D 150D 151D 152D 153D 154D 155D 156D 157D 158D 159D 160D 161D 162D 163D 164D 165D 166D 167D 168D 169D 170D 171D A7 46 CB 2CH A7 46 CB 2CH A7 46 DB 2CH AF 46 DB 2CH AF 46 EB 2CH AF 46 EB 2CH AF 4E EB 2CH AE 4E EB 2CH AE 4E EB 2CH B5 46 FB 2CH B5 54 FB 2CH B5 4C FB 2CH B5 54 FB 2CH B5 54 FB 2CH BD 54 FB 2CH BD 4C FB 2CH BD 4C FB 2CH BD 4C FB 2CH BD 44 EB 2CH C5 44 FB 2CH C5 44 FB 2CH C5 44 FB 2CH C5 45 0B 2CH C5 45 0B 2CH C5 45 0B 2CH CD 45 0B 2CH CD 45 0B 2CH CD 3D 0B 2CH CD 3D 0B 2CH CD 3D 0B 2CH D5 3D 0B 2CH 433 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s ab do u by ed PROPRIETARY AND CONFIDENTIAL 50 RAM Address oa d wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 44D 45D 46D 47D 48D 49D 50D 51D 52D 53D 54D 55D 56D 57D 58D 59D 60D 61D 62D 63D 64D 65D 66D 67D 68D 69D 70D 71D 72D 73D 74D 17 9E 19 2CH 17 A6 19 ACH 17 9E 19 ACH 17 9E 19 ACH 17 96 19 ACH 1F 96 19 ACH 1F 96 19 ACH 1F 8E 19 ACH 1F 8E 19 ACH 1F 8E 19 ACH 27 8E 19 ACH 27 8E 1A 2CH 27 8E 1A 2CH 27 8E 1A 2CH 27 8E 1A 2CH 2F 86 1A 2CH 2F 86 1A 2CH 2F 86 1A 2CH 2F 7E 1A 2CH 2F 7E 1A 2CH 2F 7E 1A 2CH 37 7E 1A 2CH 37 7E 1A ACH 37 7E 1A ACH 37 7E 1A ACH 37 7E 1A ACH 3F 7E 2A ACH 3F 7E 2A ACH 3F 76 2A ACH 3F 86 2B 2CH 3F 7E 2B 2CH 172D 173D 174D 175D 176D 177D 178D 179D 180D 181D 182D 183D 184D 185D 186D 187D 188D 189D 190D 191D 192D 193D 194D 195D 196D 197D 198D 199D 200D 201D 202D D5 3D 0B 2CH D5 3D 1B 2CH D5 3D 1B 2CH D5 3D 1B 2CH DD 3D 1B 2CH DD 3D 1B 2CH DD 35 1B 2CH DD 35 1B 2CH DD 35 1B 2CH E5 35 1B 2CH E5 35 1B 2CH E5 2D 1B 2CH E5 2D 1B 2CH E5 2D 3B 2CH ED 2D 4B 2CH ED 2D 1B A8H ED 2D 1B ACH ED 2D 17 ACH ED 2D 17 ACH ED 2D 27 ACH F5 2D 27 ACH F5 2D 27 ACH F5 2D 2B ACH F5 2D 2B ACH F5 2D 2B ACH FD 2D 2B ACH FD 2B 2B ACH FD 2B 2B ACH FD 2B 2B ACH FD 2B 2B ACH FD 23 2B ACH 434 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s ab do u by ed PROPRIETARY AND CONFIDENTIAL 50 RAM Address oa d wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Content (MSB..LSB) RAM Address Content (MSB..LSB) 75D 76D 77D 78D 79D 80D 81D 82D 83D 84D 85D 86D 87D 88D 89D 90D 91D 92D 93D 94D 95D 96D 97D 98D 99D 100D 101D 102D 103D 104D 105D 47 7E 2B 2CH 47 7E 2F 2CH 47 7E 2F 2CH 47 7E 2F 2CH 47 76 2F 2CH 4F 76 2F 2CH 4F 76 2F 2CH 4F 6E 2F 2CH 4F 6E 2F 2CH 4F 6E 2F 2CH 57 6E 2F 2CH 57 6E 2F 2CH 57 6E 3F 2CH 57 6E 3F 2CH 57 6E 3F 2CH 5F 6E 3F 2CH 5F 6E 4F 2CH 5F 6E 4F 2CH 5F 6E 4F 2CH 5F 66 4F 2CH 67 66 4F 2CH 67 66 4F 2CH 67 5E 4F 2CH 67 5E 4F 2CH 67 66 4F 2CH 67 66 4F 2CH 67 66 5F 2CH 6F 6E 5F 2CH 6F 6E 6F 2CH 6F 6E 6F 2CH 6F 6E 7F 2CH 203D 204D 205D 206D 207D 208D 209D 210D 211D 212D 213D 214D 215D 216D 217D 218D 219D 220D 221D 222D 223D 224D 225D 226D 227D 228D 229D 230D 231D 232D 233D FD 23 2B ACH FD 23 2B ACH FD 21 2B ACH FD 21 2B ACH FD 29 2B ACH FD 29 2B ACH FD 29 27 ACH FD 29 37 ACH FD 29 23 ACH FD 29 23 ACH FD 29 23 ACH FD 29 23 ACH FD 21 23 ACH FD 21 23 ACH FD 21 23 ACH FD 21 33 ACH FD 21 33 ACH FD 21 33 ACH FD 21 43 ACH FD 21 43 ACH FD 21 43 ACH FC 21 43 ACH FC 21 43 ACH FC 19 43 ACH FC 19 43 ACH FC 19 43 ACH FC 19 43 ACH FC 19 53 ACH FC 19 53 ACH FC 19 53 ACH FC 19 53 ACH 435 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ra s ab do u by ed PROPRIETARY AND CONFIDENTIAL 50 RAM Address oa d wn l Do COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Content (MSB..LSB) RAM Address Content (MSB..LSB) 106D 107D 108D 109D 110D 111D 112D 113D 114D 115D 116D 117D 118D 119D 120D 121D 122D 123D 124D 125D 126D 127D 6F 6E 7F 2CH 6F 6E 7F 2CH 77 66 7F 2CH 77 66 7F 2CH 77 5E 6F 2CH 77 5E 7F 2CH 77 5E 7F 2CH 7F 5E 7F 2CH 7F 5E 8F 2CH 7F 5E 8F 2CH 7F 5E 8F 2CH 87 56 8F 2CH 87 56 8F 2CH 87 56 8F 2CH 87 4E 8F 2CH 87 4E 8F 2CH 87 4E 8F 2CH 8F 4E 9F 2CH 8F 4E 9F 2CH 8F 4E AF 2CH 8F 4E AF 2CH 8F 4E AF 2CH 234D 235D 236D 237D 238D 239D 240D 241D 242D 243D 244D 245D 246D 247D 248D 249D 250D 251D 252D 253D 254D 255D FC 19 63 ACH FC 19 63 ACH FC 19 63 ACH FC 19 73 ACH FC 19 73 ACH FC 19 73 ACH FC 19 73 ACH FC 19 73 ACH FC 19 83 ACH FC 19 83 ACH FC 19 83 ACH FC 19 83 ACH FC 19 83 ACH FC 19 93 ACH FC 19 93 ACH FC 19 93 ACH FC 19 A3 ACH FC 19 A3 ACH FC 19 B3 ACH FC 19 B3 ACH FC 19 B3 ACH FC 19 B3 ACH 6: :2 01 07 20 t, us ug 2A ,0 ay sd ur Th on o cir ha bn of d ha ab do u ra s 50 RAM Address oa d ed by The Analog Loss Of Signal feature is available for short haul and ISDN signal levels only. (Other LOS variants are always available via the CDRC Interrupt Status and Alternate Loss of Signal registers.) For short haul and ISDN signal levels, the receiver monitors if the received signal exceeds a predefined peak amplitude and the ALOSV bit is set when this condition is not meet. The change in ALOSV state sets the ALOSI bit and can be enabled to assert the INTB. Do wn l The RLPS is able to squelch the data in response to an assertion of ALOS. Since this action is not mandatory, it is not enabled by default. However it can be desirable to do so in which case data squelching can be enabled by setting the SQUELCHE register bit to logic 1. PROPRIETARY AND CONFIDENTIAL 436 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 14.6.1 T1 Performance Monitor Mode Monitor Jack 2.42:1 RXTIP t, Rm Zo us Rt ug Zo 20 07 01 :2 The PM4351 COMET can operate in T1 Performance Monitor mode by programming the Equalizer to operate receiving a signal with a 20 dB flat loss from nominal as shown. 2A 10Zo Rm ay ,0 1:2 RXTIP Mon Rtm RXRING Mon Th ur sd Zo RXRING cir o on Rm = (10Zo - Zo)/2 = 450ohms(T1) Rt = 18.7Ohms Rtm = Zo*2^2 = 400Ohms(T1) Zo = 100ohms of bn ha The RLPS receiver values to program the equalizer for T1 Performance Monitor Mode are contained in the below table. ha d Table 109 - RLPS Equalizer Lookup Table for T1 Performance Monitor Mode Content Address (MSB..LSB) ab do u 03 FE 18 40H Content RAM Content RAM Content Address (MSB..LSB) Address (MSB..LSB) Address (MSB..LSB) 64D 03 BE 18 40H 128D 03 76 18 40H 192D 03 36 18 40H 03 FE 18 40H 65D 03 BE 18 40H 129D 03 76 18 40H 193D 03 36 18 40H 02D 03 FE 18 40H 66D 03 BE 18 40H 130D 03 76 18 40H 194D 03 36 18 40H 03D 03 FE 18 40H 67D 03 BE 18 40H 131D 03 76 18 40H 195D 03 36 18 40H 04D 03 FE 18 40H 68D 03 BE 18 40H 132D 03 76 18 40H 196D 03 36 18 40H oa d ed 01D by 00D RAM ra s RAM 03 FE 18 40H 69D 03 BE 18 40H 133D 03 76 18 40H 197D 03 36 18 40H 06D 03 FE 18 40H 70D 03 BE 18 40H 134D 03 76 18 40H 198D 03 36 18 40H 07D 03 FE 18 40H 71D 03 BE 18 40H 135D 03 76 18 40H 199D 03 36 18 40H 08D 03 F6 18 40H 72D 03 B6 18 40H 136D 03 6E 18 40H 200D 03 2E 18 40H 09D 03 F6 18 40H 73D 03 B6 18 40H 137D 03 6E 18 40H 201D 03 2E 18 40H Do wn l 05D PROPRIETARY AND CONFIDENTIAL 437 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Content RAM Content RAM Content RAM Address (MSB..LSB) Address (MSB..LSB) Address (MSB..LSB) Address 03 6E 18 40H 12D 03 F6 18 40H 76D 03 B6 18 40H 140D 13D 03 F6 18 40H 77D 03 B6 18 40H 14D 03 F6 18 40H 78D 15D 03 F6 18 40H 16D 6: 139D :2 03 B6 18 40H 01 75D 03 2E 18 40H 03 6E 18 40H 204D 03 2E 18 40H 141D 03 6E 18 40H 205D 03 2E 18 40H 03 B6 18 40H 142D 03 6E 18 40H 206D 03 2E 18 40H 79D 03 B6 18 40H 143D 03 6E 18 40H 207D 03 2E 18 40H 03 EE 18 40H 80D 03 A6 18 40H 144D 03 66 18 40H 208D 03 26 18 40H 17D 03 EE 18 40H 81D 03 A6 18 40H 145D 03 66 18 40H 209D 03 26 18 40H 18D 03 EE 18 40H 82D 03 A6 18 40H 146D 03 66 18 40H 210D 03 26 18 40H 19D 03 EE 18 40H 83D 03 A6 18 40H 147D 03 66 18 40H 211D 03 26 18 40H 20D 03 EE 18 40H 84D 03 A6 18 40H 148D 03 66 18 40H 212D 03 26 18 40H 21D 03 EE 18 40H 85D 03 A6 18 40H 149D 03 66 18 40H 213D 03 26 18 40H 22D 03 EE 18 40H 86D 03 A6 18 40H 150D 03 66 18 40H 214D 03 26 18 40H 23D 03 EE 18 40H 87D 03 A6 18 40H 151D 03 66 18 40H 215D 03 26 18 40H 24D 03 E6 18 40H 88D 03 9E 18 40H 152D 03 5E 18 40H 216D 03 1E 18 40H 25D 03 E6 18 40H 89D 03 9E 18 40H 153D 03 5E 18 40H 217D 03 1E 18 40H 26D 03 E6 18 40H 90D 154D 03 5E 18 40H 218D 03 1E 18 40H 27D 03 E6 18 40H 91D 03 9E 18 40H 155D 03 5E 18 40H 219D 03 1E 18 40H 28D 03 E6 18 40H 92D 03 9E 18 40H 156D 03 5E 18 40H 220D 03 1E 18 40H 29D 03 E6 18 40H 93D 03 9E 18 40H 157D 03 5E 18 40H 221D 03 1E 18 40H 30D 03 E6 18 40H 94D 03 9E 18 40H 158D 03 5E 18 40H 222D 03 1E 18 40H 31D 03 E6 18 40H 95D 03 9E 18 40H 159D 03 5E 18 40H 223D 03 1E 18 40H 32D 03 DE 18 40H 96D 03 96 18 40H 160D 03 56 18 40H 224D 03 16 18 40H 33D 03 DE 18 40H 97D 03 96 18 40H 161D 03 56 18 40H 225D 03 16 18 40H 34D 03 DE 18 40H 98D 03 96 18 40H 162D 03 56 18 40H 226D 03 16 18 40H 35D 03 DE 18 40H 99D 03 96 18 40H 163D 03 56 18 40H 227D 03 16 18 40H 36D 03 DE 18 40H 100D 03 96 18 40H 164D 03 56 18 40H 228D 03 16 18 40H 03 DE 18 40H 101D 03 96 18 40H 165D 03 56 18 40H 229D 03 16 18 40H 38D 03 DE 18 40H 102D 03 96 18 40H 166D 03 56 18 40H 230D 03 16 18 40H 39D 03 DE 18 40H 103D 03 96 18 40H 167D 03 56 18 40H 231D 03 16 18 40H 40D 03 D6 18 40H 104D 03 8E 18 40H 168D 03 4E 18 40H 232D 03 0E 18 40H 41D 03 D6 18 40H 105D 03 8E 18 40H 169D 03 4E 18 40H 233D 03 0E 18 40H Do PROPRIETARY AND CONFIDENTIAL 438 20 2A ,0 sd ur Th cir ha bn of ha ra s ab do u ed wn l oa d 37D 03 9E 18 40H 07 203D t, 03 F6 18 40H 03 2E 18 40H us 11D 202D ug 03 6E 18 40H ay 138D on 03 B6 18 40H o 74D (MSB..LSB) d 03 F6 18 40H Content by 10D 50 RAM PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 Content RAM Content RAM Content RAM Address (MSB..LSB) Address (MSB..LSB) Address (MSB..LSB) Address 171D 03 4E 18 40H 44D 03 D6 18 40H 108D 03 8E 18 40H 172D 45D 03 D6 18 40H 109D 03 8E 18 40H 46D 03 D6 18 40H 110D 47D 03 D6 18 40H 48D 6: 03 8E 18 40H :2 107D 01 03 D6 18 40H 03 0E 18 40H 03 0E 18 40H 03 4E 18 40H 236D 03 0E 18 40H 173D 03 4E 18 40H 237D 03 0E 18 40H 03 8E 18 40H 174D 03 4E 18 40H 238D 03 0E 18 40H 111D 03 8E 18 40H 175D 03 4E 18 40H 239D 03 0E 18 40H 03 CE 18 40H 112D 03 86 18 40H 176D 03 46 18 40H 240D 03 0E 18 40H 49D 03 CE 18 40H 113D 03 86 18 40H 177D 03 46 18 40H 241D 03 06 18 40H 50D 03 CE 18 40H 114D 03 86 18 40H 178D 03 46 18 40H 242D 03 06 18 40H 51D 03 CE 18 40H 115D 03 86 18 40H 179D 03 46 18 40H 243D 03 06 18 40H 52D 03 CE 18 40H 116D 03 86 18 40H 180D 03 46 18 40H 244D 03 06 18 40H 53D 03 CE 18 40H 117D 03 86 18 40H 181D 03 46 18 40H 245D 03 06 18 40H 54D 03 CE 18 40H 118D 03 86 18 40H 182D 03 46 18 40H 246D 03 06 18 40H 55D 03 CE 18 40H 119D 03 86 18 40H 183D 03 46 18 40H 247D 03 06 18 40H 56D 03 C6 18 40H 120D 03 7E 18 40H 184D 03 3E 18 40H 248D 03 06 18 40H 57D 03 C6 18 40H 121D 03 7E 18 40H 185D 03 3E 18 40H 249D 03 06 18 40H 58D 03 C6 18 40H 122D 186D 03 3E 18 40H 250D 03 06 18 40H 59D 03 C6 18 40H 123D 03 7E 18 40H 187D 03 3E 18 40H 251D 03 06 18 40H 60D 03 C6 18 40H 124D 03 7E 18 40H 188D 03 3E 18 40H 252D 03 06 18 40H 61D 03 C6 18 40H 125D 03 7E 18 40H 189D 03 3E 18 40H 253D 03 06 18 40H 62D 03 C6 18 40H 126D 03 7E 18 40H 190D 03 3E 18 40H 254D 03 06 18 40H 63D 03 C6 18 40H 127D 03 7E 18 40H 191D 03 3E 18 40H 255D 03 06 18 40H 20 2A ,0 sd ur Th cir ha bn of ha ra s ab do u Using the Test Pattern Generator by 14.7 03 7E 18 40H 07 235D t, 43D 234D us 03 4E 18 40H ug 170D ay 03 8E 18 40H on 106D (MSB..LSB) o 03 D6 18 40H Content d 42D 50 RAM Do wn l oa d ed The pattern generator can be configured to generate pseudo random patterns or repetitive patterns as shown in the figure below: PROPRIETARY AND CONFIDENTIAL 439 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Pattern Generator Structure 6: Figure 38 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 3 32 us 2 2A ug 1 t, 20 07 01 :2 LENGTH PS TAP Th ur sd ay ,0 The pattern generator consists of a 32-bit shift register and a single XOR gate. The XOR gate output is fed into the first stage of the shift register. The XOR gate inputs are determined by values written to the length register (PL[4:0]) and the tap register (PT[4:0], when the PS bit is low). When PS is high, the pattern detector functions as a recirculating shift register, with length determined by PL[4:0]. o on 14.7.1 Common Test Patterns PT PL PI#1 PI#2 PI#3 PI#4 TINV RINV 00 02 FF FF FF FF 0 0 00 03 FF FF FF FF 0 0 01 04 FF FF FF FF 0 0 04 05 FF FF FF FF 0 0 27 -1 00 06 FF FF FF FF 0 0 27 -1 (Fractional T1 LB Activate) 03 06 FF FF FF FF 0 0 23 -1 24 -1 by 25-1 ab do u Pattern Type ra s ha d - Pseudo-Random Pattern Generation (PS bit = 0) ed Table 110 of bn ha cir The PRGD can be configured to monitor the standardized pseudo random and repetitive patterns described in ITU-T O.151, O.152 and O.153. The register configurations required to generate these patterns and others are indicated in the two tables below: Do wn l oa d 26 -1 PROPRIETARY AND CONFIDENTIAL 440 PM4351 COMET STANDARD PRODUCT DATA SHEET PI#1 PI#2 PI#3 PI#4 27 -1 (Fractional T1 LB Deactivate) 03 06 FF FF FF FF 29 -1 (O.153) 04 08 FF FF FF 210 -1 02 09 FF FF 211 -1 (O.152, O.153) 08 0A FF FF 215 -1 (O.151) 0D 0E FF 217 -1 02 10 FF 218 -1 06 11 220 -1 (O.153) 02 13 220 -1 (O.151 QRSS bit=1) 10 13 221 -1 01 222 -1 AM PL TINV 50 PT RINV :2 1 FF 0 0 FF ug FF 0 0 FF 2A FF 0 0 FF FF 1 1 FF FF FF 0 0 FF FF FF FF 0 0 FF FF FF FF 0 0 FF FF FF FF 0 0 14 FF FF FF FF 0 0 00 15 FF FF FF FF 0 0 ay ,0 us t, 20 07 01 1 ha 6: Pattern Type sd COMBINED E1/T1 TRANSCEIVER on ISSUE 11 ra s PMC-1970624 ab do u d of bn ha cir o Th ur FF 11 16 FF FF FF FF 1 1 225 -1 02 18 FF FF FF FF 0 0 228 -1 02 1B FF FF FF FF 0 0 229 -1 01 1C FF FF FF FF 0 0 231 -1 02 1E FF FF FF FF 0 0 Do wn l oa d ed by 223 -1 (O.151) PROPRIETARY AND CONFIDENTIAL 441 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 PL PI#1 PI#2 PI#3 PI#4 TINV RINV All ones 00 00 FF FF FF FF 0 0 All zeros 00 00 FE FF FF FF 0 0 Alternating ones/zeros 00 01 FE FF FF FF 0 0 Double alternating ones/zeros 00 03 FC FF FF FF 0 0 3 in 24 00 17 22 00 20 FF 0 0 1 in 16 00 0F 01 00 FF FF 0 0 1 in 8 00 07 01 FF FF FF 0 0 1 in 4 00 03 F1 FF FF FF 0 0 Inband loopback activate 00 04 F0 FF FF FF 0 0 Inband loopback deactivate 00 02 FF FF FF 0 0 01 07 20 t, us ug 2A ,0 sd ur Th on cir o FC 6: PT :2 Pattern Type 50 - Repetitive Pattern Generation (PS bit = 1) ay Table 111 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 bn ha Notes for the Pseudo Random and Repetitive Pattern Generation Tables of 1. The PS bit and the QRSS bit are contained in the PRGD Control register ha d 2. PT = Tap Register ra s 3. PL = Shift Register Length Register ab do u 4. PI#1 = PRGD Pattern Insertion #1 Register 5. PI#2 = PRGD Pattern Insertion #2 Register by 6. PI#3 = PRGD Pattern Insertion #3 Register oa d ed 7. PI#4 = PRGD Pattern Insertion #4 Register Do wn l 8. The TINV bit and the RINV bit are contained in the PRGD Control register PROPRIETARY AND CONFIDENTIAL 442 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER 50 Using the Loopback Modes 6: 14.8 ISSUE 11 AM PMC-1970624 ug us t, 20 07 01 :2 The COMET provides four loopback modes to aid in network and system diagnostics. The network loopbacks (Payload and Line) can be initiated at any time via the P interface, but are usually initiated once an inband loopback activate code is detected. The system Diagnostic Digital loopback can be initiated at any time by the system via the P interface to check the path of system data through the framer. The Per-DS0 loopback permits the payload to be looped-back on a per-DS0 basis to allow network testing without taking an entire link off-line. ,0 2A 14.8.1 Line Loopback - Line Loopback ra s ha d of Figure 39 bn ha cir o on Th ur sd ay When LINE loopback (LINELB) is initiated by setting the LINELB bit in the Master Diagnostics Register (00AH) to logic 1, the COMET is configured to internally connect the recovered data to the transmit jitter attenuator, TJAT. In analog mode (RUNI is logic 0), the data sent to the TJAT is the recovered data from the output of the CDRC block. In digital mode (RUNI is logic 1), the data sent to the TJAT is a sampled version of the RDAT digital input. Note that when line loopback is enabled, the contents of the TJAT Reference Clock Divisor and Output Clock Divisor registers should be programmed to 2FH in T1 or FFH in E1 to correctly attenuate the jitter on the receive clock. Conceptually, the data flow through the COMET in this loopback mode is illustrated in Figure 39. In this figure, the dashed lines represent connections in digital mode (RUNI is logic 1). BTPCM BTSIG BTCLK TX ELST Transmitter T1-XBAS / E1-TRAN TJAT XLPG by ab do u BTIF TDAT TCLKO TXTIP TXRING oa d ed Line Loopback BRIF RX ELST Framer T1-FRMR / E1-FRMR Do wn l BRPCM BRSIG BRCLK PROPRIETARY AND CONFIDENTIAL RJAT CDRC RLPS RXTIP RXRING RDAT RCLKI 443 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 14.8.2 Payload Loopback ur - Payload Loopback Th Figure 40 sd ay ,0 2A ug us t, 20 07 01 :2 When PAYLOAD loopback (PAYLB) is initiated by setting the PAYLB bit in the Master Diagnostics Register (00AH) to logic 1, the COMET is configured to internally connect the output of its RX-ELST to the PCM input of its transmitter block. The data read out of RX-ELST is timed to the transmitter clock, and the transmit frame alignment indication is used to synchronize the output frame alignment of RX-ELST. The transmit frame alignment is either arbitrary (when the TX-ELST is used) or is specified by the BTFP input (when the TX-ELST is bypassed). Conceptually, the data flow through the COMET in this loopback mode is illustrated in Figure 40. Note that because the transmit and receive streams are not superframe aligned, any robbed-bit signaling in the receive stream will not fall in the correct frame once looped back and that transmit robbed-bit signaling will overwrite the looped back data if signaling insertion is enabled. Transmitter T1-XBAS / E1-TRAN TX ELST TJAT XLPG TXTIP TXRING RLPS RXTIP RXRING of bn BTIF ha BTPCM BTSIG BTCLK cir o on TDAT TCLKO BRPCM BRSIG BRCLK RX ELST Framer T1-FRMR / E1-FRMR RJAT CDRC RDAT RCLKI ed by ab do u BRIF ra s ha d Payload Loopback oa d 14.8.3 Diagnostic Digital Loopback Do wn l When Diagnostic Digital loopback (DDLB) mode is initiated by setting the DDLB bit in the Master Diagnostics Register (00AH) to logic 1, the COMET is configured to internally direct the output of the TJAT to the inputs of the receiver section. In analog mode (RUNI is logic 0), the dual-rail RZ outputs of the TJAT are directed to the dual-rail inputs of the CDRC. In digital mode (RUNI is logic 1), PROPRIETARY AND CONFIDENTIAL 444 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 - Diagnostic Digital Loopback us t, 20 Figure 41 07 01 :2 6: 50 the single-rail NRZ outputs of the TJAT are directed to the inputs of the RJAT. When configured for diagnostic digital loopback, the TUNI and RUNI bits must be set to the same value. Conceptually, the data flow through the COMET in this loopback condition is illustrated in Figure 41. In this figure, the dashed lines represent connections in digital mode (RUNI is logic 1). Transmitter T1-XBAS / E1-TRAN TX ELST TJAT XLPG TXTIP TXRING RLPS RXTIP RXRING sd ay BTIF ,0 BTPCM BTSIG BTCLK 2A ug TDAT TCLKO Th ur Diagnostic Loopback Framer T1-FRMR / E1-FRMR RX ELST RJAT CDRC cir o BRIF on BRPCM BRSIG BRCLK of bn ha RDAT RCLKI ha d 14.8.4 Per-Channel Loopback Do wn l oa d ed by ab do u ra s The T1 or E1 payload may be looped back on a per-channel or per-timeslot basis through the use of the TPSC. If all channels are looped back, the result is very similar to Payload Loopback. In order for per-channel loopback to operated correctly, the receive elastic store, RX-ELST, must be bypassed by setting the RXELSTBYP bit to logic 1 and the backplane receive interface must be set to clock master by setting the CMODE bit in the BRIF Receive Backplane Configuration register to logic 0. The LOOP bit must be set to logic 1 in the TPSC Internal Registers for each channel/timeslot desired to be looped back, and the PCCE bit in the TPSC Configuration register must be set to logic 1. When all these parameters are configured, the incoming receive channels/timeslots selected will overwrite their corresponding outgoing transmit channels/timeslots; the remaining transmit channels will pass through intact. Note that because the transmit and receive streams are not superframe aligned, any robbed-bit signaling in the receive stream will not fall in the correct frame PROPRIETARY AND CONFIDENTIAL 445 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 Using the Per-Channel Serial Controllers 01 14.9 6: 50 once looped back and that transmit robbed-bit signaling will overwrite the looped back channel data if signaling insertion is enabled. 20 07 14.9.1 Initialization ay ,0 2A ug us t, Before the TPSC (RPSC) block can be used, a proper initialization of the internal registers must be performed to eliminate erroneous control data from being produced on the block outputs. The output control streams should be disabled by setting the PCCE bit in the TPSC (RPSC) Configuration Register to logic 0. Then, all 96 locations of the TPSC (RPSC) must be filled with valid data. Finally, the output streams can be enabled by setting the PCCE bit in the TPSC (RPSC) Configuration Register to logic 1. ur sd 14.9.2 Direct Access Mode cir o on Th Direct access mode to the TPSC or RPSC is not used in the COMET. However, direct access mode is selected by default whenever the COMET is reset. The IND bit within the TPSC and RPSC Configuration Registers must be set to logic 1 after a reset is applied. bn ha 14.9.3 Indirect Access Mode ab do u ra s ha d of Indirect access mode is selected by setting the IND bit in the TPSC or RPSC Configuration Register to logic 1. When using the indirect access mode, the status of the BUSY indication bit should be polled to determine the status of the microprocessor access: when the BUSY bit is logic 1, the TPSC or RPSC is processing an access request; when the BUSY bit is logic 0, the TPSC or RPSC has completed the request. The indirect write programming sequence for the TPSC (RPSC) is as follows: by 1. Check that the BUSY bit in the TPSC (RPSC) P Access Status Register is logic 0. oa d ed 2. Write the channel data to the TPSC (RPSC) Channel Indirect Data Buffer register. Do wn l 3. Write RWB=0 and the channel address to the TPSC (RPSC) Channel Indirect Address/Control Register. 4. Poll the BUSY bit until it goes to logic 0. The BUSY bit will go to logic 1 immediately after step 3 and remain at logic 1 until the request is complete. PROPRIETARY AND CONFIDENTIAL 446 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 50 5. If there is more data to be written, go back to step 1. :2 6: The indirect read programming sequence for the TPSC (RPSC) is as follows: 07 01 1. Check that the BUSY bit in the TPSC (RPSC) P Access Status Register is logic 0. us t, 20 2. Write RWB=1 and the channel address to the TPSC (RPSC) Channel Indirect Address/Control Register. 2A ug 3. Poll the BUSY bit, waiting until it goes to a logic 0. The BUSY bit will go to logic 1 immediately after step 2 and remain at logic 1 until the request is complete. sd ay ,0 4. Read the requested channel data from the TPSC (RPSC) Channel Indirect Data Buffer register. Th ur 5. If there is more data to be read, go back to step 1. on 14.10 Isolating an Interrupt cir o When the INTB pin goes low, the following procedure may be used to isolate the interrupt source. of bn ha 1. Read the Interrupt Source Registers (Registers 007H, 008H and 009H). The bit corresponding to any block with an outstanding interrupt will be set to logic 1 in these registers. oa d ed by ab do u ra s ha d 2. Read the register(s) containing the interrupt status bits of the interrupting block in order to determine the event causing the interrupt. A typical block interrupt has two related bits: an enable bit (EVENTE for instance) and an interrupt status bit (EVENTI for instance). EVENTI will go to logic 1 when the triggering event occurs, and goes low when the register containing it is read; the setting of EVENTE has no effect on the value of EVENTI. However, a chip interrupt will only be caused if EVENTE is logic 1 and EVENTI is logic 1. Thus, both the interrupt status bit(s) and their respective enables may need to be read in order to determine which event caused an interrupt. Specific interrupt setups may differ from this model, however. Do wn l 14.11 Using the Performance Monitor Counter Values All PMON event counters are of sufficient length so that the probability of counter saturation over a one second interval is very small (less than 0.001%). The odds of any one of the counters saturating during a one second sampling interval go up as the bit error rate (BER) increases. At some point, the probability of counter PROPRIETARY AND CONFIDENTIAL 447 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 - PMON Counter Saturation Limits (E1 mode) 20 Table 112 01 :2 6: 50 saturation reaches 50%. This point varies, depending upon the framing format and the type of event being counted. The BER at which the probability of counter saturation reaches 50% is shown for various counters in Table 112 for E1 mode, and in Table 113 for T1 mode. BER LCV 4.0 X 10-3 FER 4.0 X 10-3 CRCE cannot saturate FEBE cannot saturate Counter Format LCV all FER SF ug 2A ,0 ay sd Th ur - PMON Counter Saturation Limits (T1 mode) BER on Table 113 us t, Counter cir o 5.3 x 10-3 ha 1.6 x 10-3 1.6 x 10-3 SLC(R)96 3.2 x 10-2 ESF 6.4 x 10-2 ra s SF 1.28 x 10-1 T1DM 1.83 x 10-2 SLC(R)96 2.56 x 10-1 ESF cannot saturate by ab do u CRCE ha d of bn T1DM Do wn l oa d ed Below these 50% points, the relationship between the BER and the counter event count (averaged over many one second samples) is essentially linear. Above the 50% point, the relationship between BER and the average counter event count is highly non-linear due to the likelihood of counter saturation. The following figures show this relationship for various counters and framing formats. These graphs can be used to determine the BER, given the average event count. In general, if the BER is above 10-3, the average counter event count cannot be used to PROPRIETARY AND CONFIDENTIAL 448 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 determine the BER without considering the statistical effect of occasional counter saturation. 01 :2 The following figures illustrate the expected count values for a range of Bit Error Ratios in E1 mode. 07 - LCV Count vs. BER (E1 mode) 2A 4 us Average Count Over Many 1 Second Intervals ug 5 -3 Bit Error Rate (x 10 ) t, 20 Figure 42 ay ,0 3 sd 2 Th ur 1 2000 4000 6000 8000 10000 o 0 on 0 ha cir Line Code Violation Count Per Second - FER Count vs. BER (E1 mode) of bn Figure 43 d 8 ha Average Count Over Many 1 Second Intervals 6 5 ra s 7 4 3 2 1 0 0 50 100 Do 150 200 250 Framing Bit Error Count Per Second wn l oa d ed by ab do u Bit Error Rate (x 10 -3 ) 9 Since the maximum number of CRC sub-multiframes that can occur in one second is 1000, the 10-bit FEBE and CRCE counters cannot saturate in one second. Despite this, there is not a linear relationship between BER and CRC-4 PROPRIETARY AND CONFIDENTIAL 449 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 us t, 20 07 01 :2 6: 50 block errors due to the nature of the CRC-4 calculation. At BERs below 10-4, there tends to be no more than one bit error per sub-multiframe, so the number of CRC-4 errors is generally equal to the number of bit errors, which is directly related to the BER. However, at BERs above 10-4, each CRC-4 error is often due to more than one bit error. Thus, the relationship between BER and CRCE count becomes non-linear above a 10-4 BER. This must be taken into account when using CRC-4 counts to determine the BER. Since FEBEs are indications of CRCEs at the far end, and are accumulated identically to CRCEs, the same explanation holds for the FEBE event counter. 8 CRCE 8000 8*256 ,0 log 1- 2A ug The bit error rate for E1 can be calculated from the one-second PMON CRCE count by the following equation: - CRCE Count vs. BER (E1 mode) o on Figure 44 Th ur sd ay Bit Error Rate = 1 - 10 ha cir 1.00E-02 ab do u bn ra s 1.00E-06 d 1.00E-05 of 1.00E-04 ha Bit Error Rate 1.00E-03 1.00E-07 200 400 600 800 1000 1200 CRCE by 0 Do wn l oa d ed The following figures illustrate the expected count values for a range of Bit Error Ratios in T1 mode. PROPRIETARY AND CONFIDENTIAL 450 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - LCV Count vs. BER (T1 mode) 6: Figure 45 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 8 01 Average Count Over Many 1 Second Intervals 7 07 Bit Error Rate (x 10-3 ) 6 20 5 t, 4 us 3 ug 2 2000 ,0 0 4000 6000 8000 10000 ay 0 2A 1 ur sd Line Code Violation Count Per Second - FER Count vs. BER (T1 ESF mode) on Th Figure 46 Average Count Over Many 1 Second Intervals o 8 cir 7 ha 6 bn 5 4 of 3 d 2 ha Bit Error Rate (x 10 -2 ) 9 0 ab do u 0 ra s 1 50 100 200 250 Framing Bit Error Count Per Second oa d ed by Since the maximum number of ESF superframes that can occur in one second is 333, the 9-bit BEE counter cannot saturate in one second in ESF framing format. Despite this, there is not a linear relationship between BER and BEE count, due to the nature of the CRC-6 calculation. At BERs below 10-4, there tends to be no more than one bit error per superframe, so the number of CRC-6 errors is generally equal to the number of bit errors, which is directly related to the BER. However, at BERs above 10-4, each CRC-6 error is often due to more than one bit error. Thus, the relationship between BER and BEE count becomes nonlinear above a 10-4 BER. This must be taken into account when using ESF CRC6 counts to determine the BER. wn l Do 150 PROPRIETARY AND CONFIDENTIAL 451 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 The bit error rate for T1 ESF can be calculated from the one-second PMON CRCE count by the following equation: 24 BEE 8000 24*193 01 :2 log 1- 20 - CRCE Count vs. BER (T1 ESF mode) us t, Figure 47 07 Bit Error Rate = 1 - 10 ug 1.00E-02 2A ,0 Bit Error Rate 1.00E-03 ay 1.00E-04 ur sd 1.00E-05 Th 1.00E-06 50 100 150 o 0 on 1.00E-07 200 250 300 350 ha cir CRCE of bn For T1 SF format, the CRCE and FER counts are identical, but the FER counter is smaller and should be ignored. - CRCE Count vs. BER (T1 SF mode) 20 Average Count Over Many 1 Second Intervals Do wn l oa d ed by Bit Error Rate (x 10-2 ) ab do u 18 16 14 ra s ha d Figure 48 12 10 8 6 4 2 0 0 PROPRIETARY AND CONFIDENTIAL 200 400 600 800 Bit Error Event Count Per Second 452 1000 1200 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 14.12 JTAG Support 2A - Boundary Scan Architecture Th ur sd Boundary Scan Register TDI ay ,0 Figure 49 ug us t, 20 07 01 :2 The COMET supports the IEEE Boundary Scan Specification as described in the IEEE 1149.1 standards. The Test Access Port (TAP) consists of the five standard pins, TRSTB, TCK, TMS, TDI and TDO used to control the TAP controller and the boundary scan registers. The TRSTB input is the active-low reset signal used to reset the TAP controller. TCK is the test clock used to sample data on input, TDI and to output data on output, TDO. The TMS input is used to direct the TAP controller through its states. The basic boundary scan architecture is shown in Figure 49. o on Device Identification Register Instruction Register and Decode Mux DFF TDO ab do u ra s ha d of bn ha cir Bypass Register ed by TMS Test Access Port Controller Control Select Tri-state Enable oa d TRSTB Do wn l TCK The boundary scan architecture consists of a TAP controller, an instruction register with instruction decode, a bypass register, a device identification register PROPRIETARY AND CONFIDENTIAL 453 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 01 :2 6: 50 and a boundary scan register. The TAP controller interprets the TMS input and generates control signals to load the instruction and data registers. The instruction register with instruction decode block is used to select the test to be executed and/or the register to be accessed. The bypass register offers a singlebit delay from primary input TDI to primary output TDO. The device identification register contains the device identification code. 2A ug us t, 20 The boundary scan register allows testing of board inter-connectivity. The boundary scan register consists of a shift register place in series with device inputs and outputs. Using the boundary scan register, all digital inputs can be sampled and shifted out on primary output TDO. In addition, patterns can be shifted in on primary input TDI and forced onto all digital outputs. ay ,0 TAP Controller Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd The TAP controller is a synchronous finite state machine clocked by the rising edge of primary input, TCK. All state transitions are controlled using primary TMS. The finite state machine is shown in Figure 50. PROPRIETARY AND CONFIDENTIAL 454 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - TAP Controller Finite State Machine 6: Figure 50 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 :2 TRSTB=0 1 07 Test-Logic-Reset 1 Run-Test-Idle us Select-DR-Scan 0 2A ug 0 1 1 Select-IR-Scan 0 Capture-IR ,0 Capture-DR 1 t, 1 20 0 0 sd ay 0 Shift-IR ur Shift-DR 0 o Exit1-DR cir ha bn of d Pause-IR 0 1 0 0 1 0 Exit2-DR ha ra s ab do u 0 Pause-DR Exit2-IR 1 1 Update-DR by 1 Exit1-IR 0 1 0 1 1 on Th 1 0 Update-IR 1 0 oa d ed All transitions dependent on input TMS Do wn l Test-Logic-Reset The test logic reset state is used to disable the TAP logic when the device is in normal mode operation. The state is entered asynchronously by asserting input, TRSTB. The state is entered synchronously regardless of the current TAP PROPRIETARY AND CONFIDENTIAL 455 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 controller state by forcing input, TMS high for 5 TCK clock cycles. While in this state, the instruction register is set to the IDCODE instruction. 01 :2 Run-Test-Idle 20 07 The run test/idle state is used to execute tests. us t, Capture-DR ,0 2A ug The capture data register state is used to load parallel data into the test data registers selected by the current instruction. If the selected register does not allow parallel loads or no loading is required by the current instruction, the test register maintains its value. Loading occurs on the rising edge of TCK. sd ay Shift-DR Th ur The shift data register state is used to shift the selected test data registers by one stage. Shifting is from MSB to LSB and occurs on the rising edge of TCK. o on Update-DR of bn ha cir The update data register state is used to load a test register's parallel output latch. In general, the output latches are used to control the device. For example, for the EXTEST instruction, the boundary scan test register's parallel output latches are used to control the device's outputs. The parallel output latches are updated on the falling edge of TCK. ra s ha d Capture-IR ab do u The capture instruction register state is used to load the instruction register with a fixed instruction. The load occurs on the rising edge of TCK. by Shift-IR oa d ed The shift instruction register state is used to shift both the instruction register and the selected test data registers by one stage. Shifting is from MSB to LSB and occurs on the rising edge of TCK. Do wn l Update-IR The update instruction register state is used to load a new instruction into the instruction register. The new instruction must be scanned in using the Shift-IR state. The load occurs on the falling edge of TCK. PROPRIETARY AND CONFIDENTIAL 456 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 The Pause-DR and Pause-IR states are provided to allow shifting through the test data and/or instruction registers to be momentarily paused. 01 :2 Boundary Scan Instructions 20 07 The following is an description of the standard instructions. Each instruction selects an serial test data register path between input TDI and output TDO. ug us t, BYPASS 2A The bypass instruction shifts data from input TDI to output TDO with one TCK clock period delay. The instruction is used to bypass the device. ay ,0 EXTEST ha cir o on Th ur sd The external test instruction allows testing of the interconnection to other devices. When the current instruction is the EXTEST instruction, the boundary scan register is placed between TDI and TDO. Primary device inputs can be sampled by loading the boundary scan register using the Capture-DR state. The sampled values can then be viewed by shifting the boundary scan register using the Shift-DR state. Primary device outputs can be controlled by loading patterns shifted in through input TDI into the boundary scan register using the Update-DR state. of bn SAMPLE ab do u ra s ha d The sample instruction samples all the device inputs and outputs. For this instruction, the boundary scan register is placed between TDI and TDO. Primary device inputs and outputs can be sampled by loading the boundary scan register using the Capture-DR state. The sampled values can then be viewed by shifting the boundary scan register using the Shift-DR state. IDCODE oa d ed by The identification instruction is used to connect the identification register between TDI and TDO. The device's identification code can then be shifted out using the Shift-DR state. Do wn l STCTEST The single transport chain instruction is used to test out the TAP controller and the boundary scan register during production test. When this instruction is the current instruction, the boundary scan register is connected between TDI and PROPRIETARY AND CONFIDENTIAL 457 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 TDO. During the Capture-DR state, the device identification code is loaded into the boundary scan register. The code can then be shifted out TDO using the Shift-DR state. 07 01 Boundary Scan Register Register Cell Type I.D Bit. Cell Type I.D. Bit 05 D6_OEB 1 28 OUT_CELL 0 15 D7 27 IO_CELL 1 05 D7_OEB 1 26 OUT_CELL (0) on OUT_CELL Register Bit 57 IN_CELL TCLKI 56 IN_CELL TCLKO 55 OUT_CELL 05 A0 25 IN_CELL (0) TDAT 54 OUT_CELL 0 A1 24 IN_CELL (0) TFP 53 OUT_CELL 1 A2 23 IN_CELL (0) BTCLK 52 IO_CELL 0 A3 22 IN_CELL (0) BTCLK_OEB 1 51 OUT_CELL 0 A4 21 IN_CELL (0) BTPCM 50 IN_CELL 0 A5 20 IN_CELL (0) IN_CELL 0 A6 19 IN_CELL (0) 48 IO_CELL 1 A7 18 IN_CELL (0) BTFP_OEB 1 47 OUT_CELL 1 A8 17 IN_CELL (0) CSB 46 IN_CELL 0 ALE 16 IN_CELL (0) RSTB 45 IN_CELL 1 BRFP 15 IO_CELL (0) RDB 44 IN_CELL 0 BRFP_OEB 1 14 OUT_CELL (0) WRB 43 IN_CELL 1 BRSIG 13 OUT_CELL (0) INTB 42 OUT_CELL 0 BRSIG_OEB 2 12 OUT_CELL (0) D0 41 IO_CELL 0 BRPCM 11 OUT_CELL (0) 0 BRPCM_OEB 2 10 OUT_CELL (0) cir ha bn of d ha ra s ab do u wn l ed by BTFP 49 D0_OEB 1 40 PROPRIETARY AND CONFIDENTIAL o XCLK BTSIG Do Pin/ Enable oa d 58 Th Bit HIZ3,4 sd Pin/ Enable - Boundary Scan Register ur Table 114 ay ,0 2A ug us t, 20 The boundary scan register is made up of 59 boundary scan cells, divided into input observation (in_cell), output (out_cell), and bidirectional (io_cell) cells. These cells are detailed in the pages which follow. The first 32 cells (58 down to 27) form the ID code register, and carry the code 443510CD for revision E COMET devices and 543510CD for revision F COMET devices. The remaining cells also have values which may be captured during the idcode instruction and shifted out if desired; these are included in brackets for reference. The cells are arranged as follows: OUT_CELL 458 PM4351 COMET STANDARD PRODUCT DATA SHEET Register Cell Type I.D Bit. Pin/ Enable Register Cell Type IO_CELL 1 BRCLK 9 D1_OEB 1 38 OUT_CELL 0 BRCLK_OEB 1 8 D2 37 IO_CELL 0 RSYNC 7 D2_OEB 1 36 OUT_CELL 0 RLCKI 6 D3 35 IO_CELL 0 RCLKI_OEB 1 5 D3_OEB 1 34 OUT_CELL 1 RDAT OUT_CELL (0) IO_CELL (0) OUT_CELL (0) IO_CELL (0) 3 OUT_CELL (0) 2 IN_CELL (0) 1 IO_CELL (0) 0 OUT_CELL (0) t, us 33 IO_CELL 1 D4_OEB 1 32 OUT_CELL 0 TRIMF D5 31 IO_CELL 0 NC D5_OEB 1 30 OUT_CELL 1 NC_OEB D6 29 IO_CELL 1 2A ,0 ur sd ay (0) (0) ug D4 I.D. Bit OUT_CELL 4 RDAT_OEB 1 IO_CELL :2 39 01 D1 6: Bit 07 Bit 20 Pin/ Enable COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 50 PMC-1970624 on Th Notes: cir o 1. These OEB signals, when set low, will set the corresponding bidirectional signal to an output. bn ha 2. These OEB signals, when set high, will set the corresponding output to high impedance. d of 3. When set high, TCLKO, TDAT, TFP, and RSYNC will be set to high impedance. ra s ha 4. HIZ is the first bit in the boundary scan chain. Do wn l oa d ed by ab do u 5. Bits 59:56 represent the revision identification code. "0100" indicates revision E. "0101" indicates revision F. PROPRIETARY AND CONFIDENTIAL 459 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 6: 50 - Input Observation Cell (IN_CELL) IDCODE Input Pad 07 01 Scan Chain Out :2 Figure 51 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 20 G1 us C ,0 I.D. Code bit D ug 12 1 2 MUX 12 2A SHIFT-DR t, G2 INPUT to internal logic ay 12 sd CLOCK-DR Th ur Scan Chain In Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on In this diagram and those that follow, CLOCK-DR is equal to TCK when the current controller state is SHIFT-DR or CAPTURE-DR, and unchanging otherwise. The multiplexer in the centre of the diagram selects one of four inputs, depending on the status of select lines G1 and G2. The ID Code bit is as listed in the table above. PROPRIETARY AND CONFIDENTIAL 460 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Scan Chain Out 1 07 ug SHIFT - DR MUX us G1 G2 IDCODE D ay 1 2 ,0 1 2 MUX 2A 1 2 I.D. code bit C ur sd 1 2 Th CLOCK-DR UPDA TE- DR Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Scan Chain In PROPRIETARY AND CONFIDENTIAL 20 1 t, OUTPUT or Enable f rom syst em logic 01 G1 EXTEST 461 6: 50 - Output Cell (OUT_CELL) :2 Figure 52 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 D C OUTPUT or Enable PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Bidirectional Cell (IO_CELL) :2 6: Figure 53 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 1 07 2A D ur C Th I.D. code bit OUTPUT to pin ,0 12 1 2 MUX 12 12 ay INPUT from pin sd SHIFT-DR MUX ug G1 G2 t, 1 us OUTPUT from internal logic IDCODE INPUT to internal logic 20 G1 EXTEST D C on CLOCK-DR o UPDATE-DR ha cir Scan Chain In bn - Layout of Output Enable and Bidirectional Cells Scan Chain Out ha d of Figure 54 01 Scan Chain Out OUT_CELL ab do u ra s OUTPUT ENABLE from internal logic (0 = drive) IO_CELL Scan Chain In Do wn l oa d ed by INPUT to internal logic OUTPUT from internal logic PROPRIETARY AND CONFIDENTIAL 462 I/O PAD PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER ABSOLUTE MAXIMUM RATINGS :2 6: 15 50 AM PMC-1970624 20 07 01 Maximum ratings are the worst case limits that the device can withstand without sustaining permanent damage. They are not indicative of normal mode operation conditions. -55C to +125C Storage Temperature -65C to +150C Voltage on VDD with Respect to GND -0.3V to 4.6V Voltage on BIAS with respect to GND VDD - 0.3V to 5.5V Voltage on Any Pin -0.3V to BIAS + 0.3V Static Discharge Voltage 1000 V 2A ,0 ay sd ur on Maximum DC current on any pin Th Latchup current on any pin o Maximum Lead Temperature 100 mA 20 mA +230 C +150 C Do wn l oa d ed by ab do u ra s ha d of bn ha cir Maximum Junction Temperature PROPRIETARY AND CONFIDENTIAL ug us t, Ambient Temperature under Bias 463 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER D.C. CHARACTERISTICS :2 6: 16 50 AM PMC-1970624 Max Power Supply 3.135 3.3 3.465 Volts BIAS 5 V Tolerant Bias 5.0 5.5 Volts IBIAS Current into 5 V Bias VIL Input Low Voltage Guaranteed Input LOW Voltage BIAS Volts Guaranteed Input HIGH Voltage 0.4 Volts VDD = min, IOL = -6 mA for BTCLK and BRCLK, -2 mA for all other digital outputs. Note 3 2.4 Volts VDD = min, IOH = 6 mA for BTCLK and BRCLK, 2 mA for all other digital outputs. Note 3 2.0 Volts TTL Schmitt trigger o bn ha cir 2.0 Output or Bidirectional Low Voltage 0.25 d ha ra s (TTL Only) ab do u (TTL Only) Reset Input High Voltage VT- Reset Input Low Voltage 0.8 Do wn l oa d VT+ Output or Bidirectional High Voltage ed by VOH PROPRIETARY AND CONFIDENTIAL 07 Volts of VOL 2A 0.8 0 Input High Voltage (TTL Only) ,0 VBIAS = 5.5V (TTL Only) VIH Conditions A sd 6.0 ay VDD Units ug Typ ur VDD Min Th Parameter on Symbol t, - D.C. Characteristics us Table 115 20 (Typical Conditions: TA = 25C, VDD = 3.3 V, VBIAS = 5 V) 01 TA = -40C to +85C, VDD = 3.3 V 5%, VDD VBIAS 5.5 V 464 Volts PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER Typ Max Units VTH Reset Input Hysteresis Voltage IILPU Input Low Current 10 60 100 A IIHPU Input High Current -10 0 +10 A IIL Input Low Current -10 0 +10 IIH Input High Current -10 0 CIN Input Capacitance COUT Output Capacitance CIO Bi-directional Capacitance IDDOPMAX Operating Current Volts 01 0.5 07 20 t, us ug VIH = VDD. Notes 2, 3 pF Excluding Package, Package Typically 2 pF 5 pF Excluding Package, Package Typically 2 pF 5 pF Excluding Package, Package Typically 2 pF 250 mA VDD = 3.465 V, T1 mode, 1.544 MHz backplane, transmitting all ones, short haul 550 to 660 ft. Outputs Unloaded 416 mW VDD = 3.465 V, 85 C case temperature, T1 mode, 1.544 MHz backplane, transmitting 50% ones density, short haul 0 ft. Outputs Unloaded 2A A d of bn ha cir o on Th ur sd ay +10 ha oa d wn l Do 465 VIH = VDD. Notes 1, 3 VIL = GND. Notes 2, 3 ra s ab do u Power Dissipation PROPRIETARY AND CONFIDENTIAL VIL = GND. Notes 1, 3 A 5 ed by PDISS Conditions :2 Min 50 Parameter 6: Symbol AM ISSUE 11 ,0 PMC-1970624 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 6: 50 Notes on D.C. Characteristics: 01 :2 1. Input pin or bi-directional pin with internal pull-up resistor. 07 2. Input pin or bi-directional pin without internal pull-up resistor Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug us t, 20 3. Negative currents flow into the device (sinking), positive currents flow out of the device (sourcing). PROPRIETARY AND CONFIDENTIAL 466 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 A.C. TIMING CHARACTERISTICS 17.1 Microprocessor Interface Timing Characteristics 01 :2 6: 17 20 t, - Microprocessor Read Access (Figure 55) us Table 116 07 (TA = -40C to +85C, VDD = 3.3 V 5%) Parameter tSAR Address to Valid Read Set-up Time 10 ns tHAR Address to Valid Read Hold Time 5 ns tSALR Address to Latch Set-up Time 10 ns tHALR Address to Latch Hold Time 10 ns tVL Valid Latch Pulse Width 20 ns tSLR Latch to Read Set-up 0 ns tHLR Latch to Read Hold 5 ns tPRD Valid Read to Valid Data Propagation Delay 80 ns tZRD Valid Read Negated to Output Tri-state 20 ns tZINTH Valid Read Negated to INTB high 50 ns Do wn l oa d ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug Symbol PROPRIETARY AND CONFIDENTIAL 467 Min Max Units PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Microprocessor Read Access Timing 6: Figure 55 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 Address 20 Valid 07 A[8:0] :2 tSAR tHAR tV L 2A ug tHALR us t, tS ALR ,0 ALE tHLR sd ay tS LR tZ INTH on Th ur (CSB+RDB) ha cir o INTB bn tPRD Valid Data ha d of D[7:0] tZ RD ab do u ra s Notes on Microprocessor Read Timing: 1. Output propagation delay time is the time in nanoseconds from the 1.4 Volt point of the reference signal to the 1.4 Volt point of the output. ed by 2. Maximum output propagation delays are measured with a 50 pF load on the Microprocessor Interface data bus, (D[7:0]). oa d 3. A valid read cycle is defined as a logical OR of the CSB and the RDB signals. Do wn l 4. Microprocessor Interface timing applies to normal mode register accesses only. PROPRIETARY AND CONFIDENTIAL 468 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 5. When a set-up time is specified between an input and a clock, the set-up time is the time in nanoseconds from the 1.4 Volt point of the input to the 1.4 Volt point of the clock. 20 07 01 6. When a hold time is specified between an input and a clock, the hold time is the time in nanoseconds from the 1.4 Volt point of the clock to the 1.4 Volt point of the input. ug us t, 7. In non-multiplexed address/data bus architectures ALE can be held high; parameters tSALR, tHALR, tVL, and tSLR, tHLR are not applicable. ,0 - Microprocessor Write Access (Figure 56) ay Table 117 2A 8. Parameter tHAR is not applicable when address latching is used. Parameter tSAW Address to Valid Write Set-up Time 10 ns tSDW Data to Valid Write Set-up Time 20 ns tSALW Address to Latch Set-up Time 10 ns tHALW Address to Latch Hold Time 10 ns tVL Valid Latch Pulse Width 20 ns tSLW Latch to Write Set-up 0 ns tHLW Latch to Write Hold 5 ns tHDW Data to Valid Write Hold Time 5 ns Address to Valid Write Hold Time 5 ns Valid Write Pulse Width 40 ns cir ha bn of d ha Do wn l oa d ed by ab do u ra s tHAW tVWR o on Th ur sd Symbol PROPRIETARY AND CONFIDENTIAL 469 Min Max Units PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Microprocessor Write Access Timing A[8:0] :2 6: Figure 56 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 07 tH ALW tVL 20 tSALW 01 Valid Address tHLW us t, tS LW 2A ug ALE tVWR tH AW ,0 tSAW sd ay (CSB+WRB) Th ur tS DW Valid Data cir o on D[7:0] tH DW ha Notes on Microprocessor Interface Write Timing: bn 1. A valid write cycle is defined as a logical OR of the CSB and the WRB signals. ha d of 2. Microprocessor Interface timing applies to normal mode register accesses only. ab do u ra s 3. In non-multiplexed address/data bus architectures, ALE can be held high, parameters tSALW, tHALW, tVL, and tSLW, tHLW are not applicable. 4. Parameters tHAW and tSAW are not applicable if address latching is used. ed by 5. Output propagation delay time is the time in nanoseconds from the 1.4 Volt point of the reference signal to the 1.4 Volt point of the output. Do wn l oa d 6. When a set-up time is specified between an input and a clock, the set-up time is the time in nanoseconds from the 1.4 Volt point of the input to the 1.4 Volt point of the clock. 7. When a hold time is specified between an input and a clock, the hold time is the time in nanoseconds from the 1.4 Volt point of the clock to the 1.4 Volt point of the input. PROPRIETARY AND CONFIDENTIAL 470 PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER 50 Transmit Backplane Interface (Figure 57, Figure 58) 6: 17.2 ISSUE 11 AM PMC-1970624 01 07 Typ Max Units BTCLK Average Frequency3 (T1 mode, CMS=0, RATE[1:0]='b00) Typ - 200 ppm 1.544 Typ + 200 ppm MHz BTCLK Average Frequency3 (CMS=0, RATE[1:0]='b01) Typ - 200 ppm 2.048 Typ + 200 ppm MHz BTCLK Average Frequency3 (T1 mode, CMS=1, RATE[1:0]='b00) Typ - 200 ppm 3.088 Typ + 200 ppm MHz Typ - 200 ppm 4.096 Typ + 200 ppm MHz BTCLK Average Frequency3 (CMS=0, RATE[1:0]='b11) or (CMS=1, RATE[1:0]='b10) Typ - 200 ppm 8.192 Typ + 200 ppm MHz BTCLK Average Frequency3 (CMS=1, RATE[1:0]='b11) Typ - 200 ppm 16.384 Typ + 200 ppm MHz 65 % of bn ha cir o BTCLK Duty Cycle4 35 d us ug 2A ,0 ay on Th BTCLK Average Frequency3 (CMS=0, RATE[1:0]='b10) or (CMS=1, RATE[1:0]='b01) 20 Min t, Description sd Symbol - Transmit Backplane Interface ur Table 118 :2 (TA = -40C to +85C, VDD = 3.3 V 5%) BTCLK to Backplane Input Set-up Time1 20 ns tHBTCLK BTCLK to Backplane Input Hold Time2 20 ns tPBTFP BTCLK to BTFP Output Propagation Delay -20 Do wn l oa d ed by ab do u ra s ha tSBTCLK PROPRIETARY AND CONFIDENTIAL 471 50 ns PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 6: :2 BTPCM, BTSIG, BTFP (input) 01 Valid tS BTC LK t, 20 tH BTC LK ug us BTCLK ,0 2A Data Sam pled on Rising Edge ay BTPCM, BTSIG, BTFP (input) ur sd Valid tH BTC LK on Th tS BTC LK cir o BTCLK Do wn l oa d ed by ab do u ra s ha d of bn ha Data Sam pled on Falling Edge PROPRIETARY AND CONFIDENTIAL 50 - Backplane Transmit Input Timing Diagram 07 Figure 57 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 472 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Backplane Transmit Output Timing Diagram 6: Figure 58 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 BTFP (output) 07 01 :2 BTCLK us t, 20 Valid ug tPBTF P ay ,0 2A Fram e Pulse Output on Rising Edge Th ur sd BTCLK Valid cir o on BTFP (output) ha tPBTF P d Receive Backplane Interface (Figure 59, Figure 60) ha 17.3 of bn Fram e Pulse Output on Falling Edge - Receive Backplane Interface ab do u Table 119 ra s (TA = -40C to +85C, VDD = 3.3 V 5%) Do wn l oa d ed by Symbol Description Min Typ Max Units BRCLK Average Frequency3 (T1 mode, CMS=0, RATE[1:0]='b00) Typ - 200 ppm 1.544 Typ + 200 ppm MHz BRCLK Average Frequency3 (CMS=0, RATE[1:0]='b01) Typ - 200 ppm 2.048 Typ + 200 ppm MHz BRCLK Average Frequency3 (T1 mode, CMS=1, RATE[1:0]='b00) Typ - 200 ppm 3.088 Typ + 200 ppm MHz PROPRIETARY AND CONFIDENTIAL 473 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 Min Typ Max BRCLK Average Frequency3 (CMS=0, RATE[1:0]='b10) or (CMS=1, RATE[1:0]='b01) Typ - 200 ppm 4.096 Typ + 200 ppm MHz BRCLK Average Frequency3 (CMS=0, RATE[1:0]='b11) or (CMS=1, RATE[1:0]='b10) Typ - 200 ppm 8.192 Typ + 200 ppm MHz BRCLK Average Frequency3 (CMS=1, RATE[1:0]='b11) Typ - 200 ppm 16.384 BRCLK Duty Cycle4 35 tSBRFP BRFP to BRCLK Input Set-up Time1 20 tHBRFP BRFP to BRCLK Input Hold Time2 20 tPBRCLK BRCLK to Backplane Output Signals Propagation Delay7,8 -20 50 ns tZBRCLK BRCLK to Backplane Output Signals High Impedance -20 30 ns 6: :2 01 07 20 t, us ug MHz 65 % ns ay ,0 2A Typ + 200 ppm sd ns ur Th on o ha bn of d ha ra s ab do u by ed oa d wn l Do PROPRIETARY AND CONFIDENTIAL Units 50 Description cir Symbol COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 474 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Backplane Receive Input Timing Diagram :2 6: Figure 59 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 Valid BRFP (input) 07 tS BRFP t, 20 tH BRFP 2A ug us BRCLK sd ay ,0 Fram e Pulse Sam pled on Rising Edge BRFP (input) Th ur Valid tH BRFP o on tS BRFP bn ha cir BRCLK Do wn l oa d ed by ab do u ra s ha d of Fram e Pulse Sam pled on Falling Edge PROPRIETARY AND CONFIDENTIAL 475 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Backplane Receive Output Timing Diagram 6: Figure 60 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 BRPCM, BRSIG 07 01 :2 BRCLK us t, 20 Valid 2A ug tPBRCLK tZ BRCLK ay ,0 Data Output on Rising Edge Th ur sd BRCLK Valid cir o on BRFP (output) ha tPBRCLK Do wn l oa d ed by ab do u ra s ha d of bn FP Output on Rising Edge PROPRIETARY AND CONFIDENTIAL 476 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 BRPCM, BRSIG 01 :2 6: 50 BRCLK 20 07 Valid tPBRCLK us t, tZ BRCLK 2A ug Data Output on Falling Edge ur sd ay ,0 BRCLK BRFP (output) on Th Valid o tPBRCLK bn Receive Digital Interface (Figure 61) of 17.4 ha cir FP Output on Falling Edge by ab do u Symbol - Receive Digital Interface ra s Table 120 ha d (TA = -40C to +85C, VDD = 3.3 V 5%) Description Min RCLKI Frequency (nominally 1.544 MHz 130 ppm or 2.048 MHz 50 ppm) Max Units 2.1 MHz 70 % 30 tSRCLKI RCLKI to RDAT Setup Time1 20 ns tHRCLKI RCLKI to RDAT Hold Time2 20 ns Do wn l oa d ed RCLKI Duty Cycle4 PROPRIETARY AND CONFIDENTIAL 477 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 50 - Digital Receive Interface Timing Diagram :2 6: Figure 61 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 01 Valid RDAT 07 tS RCLKI t, 20 tH RCLKI Valid 2A sd ay RDAT ,0 W ith RFALL bit = 0 ug us RCLKI Th ur tS RCLKI cir o on RCLKI tH RCLKI Transmit Digital Interface (Figure 62) of 17.5 bn ha W ith RFALL bit = 1 ra s - Transmit Digital Interface Description Min Max Units tTCLKI TCLKI Frequency, typically 1.544 MHz 130 ppm in T1 mode or 2.048 MHz 50 ppm in E1 mode 1.543 2.047 1.545 2.049 MHz MHz tHTCLKI TCLKI High Duration4 160 ns tLTCLKI TCLKI Low Duration4 160 ns XCLK Frequency, typically 1.544 MHz 100 ppm in T1 mode or 2.048 MHz 100 ppm in E1 mode 1.543 2.047 wn l oa d by ab do u Symbol ed Table 121 ha d (TA = -40C to +85C, VDD = 3.3 V 5%) Do tXCLK PROPRIETARY AND CONFIDENTIAL 478 1.545 2.049 MHz MHz PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 Description Min Max Units tHXCLK XCLK High Duration4 160 ns tLXCLK XCLK Low Duration4 160 tPTCLKO TCLKO to Digital Transmit Output Signals Propagation Delay -20 ay ,0 2A tHTCLKI tTCLKI t H XCLK cir o on Th ur sd tLTCLKI t XCLK Do wn l oa d ed by ab do u ra s ha d of bn ha t L XCLK PROPRIETARY AND CONFIDENTIAL 479 :2 01 07 20 t, us - Digital Transmit Interface Timing Diagram ug Figure 62 50 Symbol 6: PMC-1970624 50 ns ns PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 TDAT, TFP 01 :2 6: 50 TCLKO 20 07 Valid us t, tPTCLK O 2A ug W ith TRISE bit = 0 sd ay ,0 TCLKO TDAT, TFP on tPTCLK O Th ur Valid JTAG Port Interface (Figure 63) bn 17.6 ha cir o W ith TRISE bit = 1 ha Min TCK Frequency Max Units 4 MHz 60 % TCK Duty Cycle 40 TMS Set-up time to TCK 50 ns TMS Hold time to TCK 50 ns tSTDI TDI Set-up time to TCK 50 ns tHTDI TDI Hold time to TCK 50 ns tPTDO TCK Low to TDO Valid 2 by tSTMS wn l oa d tHTMS Do Description ed ab do u Symbol - JTAG Port Interface ra s Table 122 d of (TA = -40C to +85C, VDD = 3.3 V 5%) PROPRIETARY AND CONFIDENTIAL 480 50 ns PM4351 COMET STANDARD PRODUCT DATA SHEET COMBINED E1/T1 TRANSCEIVER AM ISSUE 11 Description Min Max Units tVTRSTB TRSTB Pulse Width 100 ns :2 01 - JTAG Port Interface Timing 20 07 Figure 63 50 Symbol 6: PMC-1970624 ug tH TMS 2A tS TMS us t, TCK ay ,0 TMS tH TDI ur sd tS TDI cir o on Th TDI d ab do u ra s ha TDO tP TDO of bn ha TCK tV TRSTB ed by TRSTB Do wn l oa d Notes on Input Timing: 1. When a set-up time is specified between an input and a clock, the set-up time is the time in nanoseconds from the 1.4 Volt point of the input to the 1.4 Volt point of the clock. PROPRIETARY AND CONFIDENTIAL 481 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 :2 6: 50 2. When a hold time is specified between an input and a clock, the hold time is the time in nanoseconds from the 1.4 Volt point of the clock to the 1.4 Volt point of the input. 20 07 01 3. BTCLK and BRCLK instantaneous period variation of +/- 8% (typical) can be tolerated by the device, as long as the frequency specification of +/- 200ppm is complied with. ug us t, 4. High pulse width is measured from the 1.4 Volt points of the rise and fall ramps. Low pulse width is measured from the 1.4 Volt points of the fall and rise ramps. ,0 2A 5. XCLK accuracy is 100 ppm. ur sd ay 6. TCLKI can be a jittered clock signal subject to the minimum high and low durations tHTCLKI, tLTCLKI. These durations correspond to nominal XCLK input frequencies. on Th Notes on Output Timing: cir o 7. Output propagation delay time is the time in nanoseconds from the 1.4 Volt point of the reference signal to the 1.4 Volt point of the output. Do wn l oa d ed by ab do u ra s ha d of bn ha 8. Maximum output propagation delays are measured with a 50 pF load on the output. PROPRIETARY AND CONFIDENTIAL 482 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER ORDERING AND THERMAL INFORMATION :2 6: 18 50 AM PMC-1970624 - Ordering Information Part No. Description PM4351-RI 80-Pin Metric Quad Flat Pack (MQFP) PM4351-NI 81-Ball Chip Array Ball Grid Array (CABGA) PM4351-RGI 80-Pin MQFP 14x14x2 mm (ROHS Compliant) PM4351-NGI 81-Ball CABGA, 9 x 9x1.4 mm (ROHS Compliant) 07 20 t, us ug 2A ,0 - Thermal Information PM4351-RI -40C to 85C cir o Dense Board1 JEDEC Board -40C to 85C ha Dense Board 2 3 bn JEDEC Board4 Forced Air (Linear Feet per Minute) Conv 100 200 300 400 500 62.1 54.8 49.1 45.0 42.4 41.1 43.2 40.7 39.2 38.5 38.2 38.0 99.5 92.9 87.8 84.0 81.0 78.5 47.8 45.8 44.4 43.5 43.0 42.7 of PM4351-NI Theta J-A Th Case Temperature on Part No. ur sd ay Table 124 01 Table 123 ab do u ra s ha d 1. - Dense Board is defined as a 3S3P board and consists of a 3x3 array of PM4351-RI devices located as close to each other as board design rules allow. All PM4351-RI devices are assumed to be dissipating 0.416 Watts. Theta J-A listed is for the device in the middle of the array. 2. - JEDEC Board Theta J-A is the measured value for a single thermal device in the same package on a 2S2P board following EIA/JESD 51-3. oa d ed by 3. - Dense Board is defined as a 3S3P board and consists of a 3x3 array of PM4351-NI devices located as close to each other as board design rules allow. All PM4351-NI devices are assumed to be dissipating 0.416 Watts. Theta J-A listed is for the device in the middle of the array. Do wn l 4. - JEDEC Board Theta J-A is the measured value for a single thermal device in the same package on a 2S2P board following EIA/JESD 51-3. PROPRIETARY AND CONFIDENTIAL 483 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER MECHANICAL INFORMATION :2 6: 19 50 AM PMC-1970624 07 01 PM4351-RI Package 20 D A ug us 80 t, D1 2A 1 E e ,0 Pin 1 Designator ur sd ay E1 8-12 DEG o on Th 8-12 DEG cir A2 bn ha SEE DETAIL A of 0-10 DEG. PLANE d ha C GAGE PLANE, 0.25 ABOVE SEATING PLANE. b L ab do u ccc C 80 PIN METRIC PLASTIC QUAD FLATPACK-MQFP 14 x 14 x 2.0 MM Dim. A Min. 2.00 0.05 1.95 Nom. 2.15 0.15 2.00 Max. 2.35 0.25 2.10 D A2 wn l A1 Do PROPRIETARY AND CONFIDENTIAL LEAD COPLANARITY DETAIL A PACKAGE TYPE: by C 0-7 DEG BODY SIZE: ed 2) DIMENSIONS SHOWN ARE NOMINAL WITH TOLERANCES AS INDICATED. 3) FOOT LENGTH "L" IS MEASURED AT 0.13-0.23 oa d NOTES: 1) ALL DIMENSIONS IN MILLIMETER. A1 ra s SEATING STANDOFF .25 A 484 D1 E E1 L 16.95 13.90 16.95 13.90 0.73 17.20 14.00 17.20 14.00 0.88 17.45 14.10 17.45 14.10 1.03 e b ccc 0.22 0.65 0.38 0.10 PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER AM PMC-1970624 9 D 8 7 6 -B- 5 4 D1 6: -A- 3 :2 0.20 2 07 A B 20 A1 BA LL I.D. IN K MA RK C us t, D E1 E ug E F 2A G ,0 H ay J sd e ur on Th A2 cir SE AT IN G PLA N E A -C- 0.10 o b A1 NO TE S: ha .15 A C A S B S .08 A C wn l oa d ed by ab do u ra s ha d of bn 1) ALL D IM EN SIO NS IN M ILLIM ET ER . Do PROPRIETARY AND CONFIDENTIAL 485 A1 BA LL CO R NE R 1 01 A1 BA LL CO R NE R 50 PM4351-NI Package PM4351 COMET STANDARD PRODUCT DATA SHEET ISSUE 11 COMBINED E1/T1 TRANSCEIVER 50 AM PMC-1970624 6: CONTACTING PMC-SIERRA, INC. 01 07 (604) 415-6200 20 Fax: t, (604) 415-6000 us Tel: :2 PMC-Sierra, Inc. 105-8555 Baxter Place Burnaby, BC Canada V5A 4V7 document@pmc-sierra.com info@pmc-sierra.com apps@pmc-sierra.com Web Site: http://www.pmc-sierra.com ed by ab do u ra s ha d of bn ha cir o on Th ur sd ay ,0 2A ug Document Information: Corporate Information: Application Information: wn l oa d None of the information contained in this document constitutes an express or implied warranty by PMC-Sierra, Inc. as to the sufficiency, fitness or suitability for a particular purpose of any such information or the fitness, or suitability for a particular purpose, merchantability, performance, compatibility with other parts or systems, of any of the products of PMC-Sierra, Inc., or any portion thereof, referred to in this document. PMC-Sierra, Inc. expressly disclaims all representations and warranties of any kind regarding the contents or use of the information, including, but not limited to, express and implied warranties of accuracy, completeness, merchantability, fitness for a particular use, or non-infringement. Do In no event will PMC-Sierra, Inc. be liable for any direct, indirect, special, incidental or consequential damages, including, but not limited to, lost profits, lost business or lost data resulting from any use of or reliance upon the information, whether or not PMC-Sierra, Inc. has been advised of the possibility of such damage. (c) 2005 PMC-Sierra, Inc. PMC-1970624 (R11) ref PMC-1961273(R11) PMC-Sierra, Inc. Issue date: Nov 2005 105 - 8555 Baxter Place Burnaby, BC Canada V5A 4V7 604 .415.6000