Never stop thinking.
Data Sheet, DS3, Jan. 2003
Wired
Communications
IWE8
Interworking Element for
8 E1/T1 Lines
PXB 4219E, PXB 4220E, PXB
4221E, Version 3.4
Edition 2003-01-20
Published by Infineon Technologies AG,
St.-Martin-Strasse 53,
81669 München, Germany
© Infineon Technologies AG 2003.
All Rights Reserved.
Attention please!
The information herein is given to describe certain components and shall not be considered as warranted
characteristics.
Terms of delivery and rights to technical change reserved.
We hereby disclaim any and all warranties, including but not limited to warranties of non-infringement, regarding
circuits, descriptions and charts stated herein.
Infineon Technologies is an approved CECC manufacturer.
Information
For further information on technology, delivery terms and conditions and prices please contact your nearest
Infineon Technologies Office in Germany or our Infineon Technologies Representatives worldwide
(www.infineon.com).
Warnings
Due to technical requirements components may contain dangerous substances. For information on the types in
question please contact your nearest Infineon Technologies Office.
Infineon Technologies Components may only be used in life-support devices or systems with the express written
approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure
of that life-support device or system, or to affect the safety or effectiveness of that device or system. Life support
devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain
and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may
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ABM®, ACE®, AOP®, ARCOFI®, ASM®, ASP®, DigiTape®, DuSLIC®, EPIC®, ELIC®,
FALC®, GEMINAX®, IDEC®, INCA®, IOM®, IPAT®-2, ISAC®, ITAC®, IWE®, IWORX®,
MUSAC®, MuSLIC®, OCTAT®, OptiPort®, POTSWIRE®, QUAT®, QuadFALC®,
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10BaseV®, 10BaseVX® are registered trademarks of Infineon Technologies AG.
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trademark of Linus Torvalds.
The information in this document is subject to change without notice.
Data Sheet
Revision History: 2003-01-20 DS3
Previous Version: Preliminary Data Sheet, DS2, 2002-05-06
Page Subjects (major changes since last revision)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 3 2003-01-20
1Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14
1.1 Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15
1.2 Logic Symbol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
1.3 Typical Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
1.3.1 Line Card . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
1.3.2 Echo Canceller . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
1.4 Differences Between PXB4220 And PXB4219 . . . . . . . . . . . . . . . . . . . . . 21
1.5 Differences Between PXB4220 And PXB4221 . . . . . . . . . . . . . . . . . . . . . 21
2 Pin Descriptions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
2.1 Pin Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
2.2 Pin Definitions and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
2.2.1 Generic Framer Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
2.2.2 UTOPIA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
2.2.3 IMA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
2.2.4 Clock Recovery Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
2.2.5 Microprocessor Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
2.2.6 External RAM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
2.2.7 Test Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
2.2.8 Miscellaneous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
2.2.9 Power Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
2.2.10 Not Connected Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
3 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 34
3.1 Operating Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
3.1.1 ATM Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
3.1.2 AAL Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
3.1.2.1 Unstructured CES Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 35
3.1.2.2 Structured CES Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 36
3.2 Functional Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
3.3 Functional Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
4 Operational Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
4.1 ATM Transmit Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
4.1.1 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
4.1.1.1 ATM Transmit Buffer Filling Level . . . . . . . . . . . . . . . . . . . . . . . . . . . 42
4.1.1.2 Cell Discarding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
4.1.1.3 Cell rate de-coupling: Idle/Unassigned Cell Insertion . . . . . . . . . . . . 43
4.1.1.4 Cell Payload Scrambling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
4.1.1.5 HEC Generation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 44
4.1.2 Setup of ATM Transmit Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 45
4.2 ATM Receive Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
4.2.1 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
4.2.1.1 Cell Delineation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 46
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 4 2003-01-20
4.2.1.2 HEC Check: Header Error Detection and Correction . . . . . . . . . . . . 48
4.2.1.3 Cell Payload Descrambling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 49
4.2.1.4 Idle, Physical Layer or Unassigned Cell Deletion . . . . . . . . . . . . . . . 49
4.2.2 Setup of ATM Receive Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 51
4.3 AAL Segmentation Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
4.3.1 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
4.3.1.1 Segmentation Port Decorrelation . . . . . . . . . . . . . . . . . . . . . . . . . . . . 52
4.3.1.2 Segmentation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53
4.3.1.3 Transport of the Framer Port Number . . . . . . . . . . . . . . . . . . . . . . . . 53
4.3.1.4 Transport of CAS Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54
4.3.1.5 CAS Conditioning and Freezing Upstream . . . . . . . . . . . . . . . . . . . . 54
4.3.1.6 Segmentation Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
4.3.1.7 Padding Partially Filled Cells . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 55
4.3.2 Setup of AAL Segmentation Channels . . . . . . . . . . . . . . . . . . . . . . . . . 56
4.4 AAL Reassembly Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
4.4.1 Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
4.4.1.1 Port and Channel Identification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 58
4.4.1.2 Sequence Number Protection field check . . . . . . . . . . . . . . . . . . . . . 58
4.4.1.3 Sequence Number field check . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
4.4.1.4 RTS Extraction and Verification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59
4.4.1.5 Pointer Field Detection and Verification . . . . . . . . . . . . . . . . . . . . . . . 59
4.4.1.6 CAS Conditioning and Freezing Downstream . . . . . . . . . . . . . . . . . . 60
4.4.1.7 Insertion of Dummy Cells at Cell Loss . . . . . . . . . . . . . . . . . . . . . . . . 60
4.4.1.8 Reassembly Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 60
4.4.1.9 Handling of Reassembly Buffer Overflow . . . . . . . . . . . . . . . . . . . . . 61
4.4.1.10 Handling of Reassembly Buffer Underflow . . . . . . . . . . . . . . . . . . . . 61
4.4.1.11 Synchronization of SDT Structure with Port Structure . . . . . . . . . . . . 62
4.4.2 Setup . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
4.4.2.1 Setup of Reassembly Channels . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62
4.4.2.2 Physical Reassembly Buffer Size . . . . . . . . . . . . . . . . . . . . . . . . . . . 63
4.4.2.3 Initialization of the Reassembly Buffer . . . . . . . . . . . . . . . . . . . . . . . . 64
4.4.2.4 Re-Initialization of the Reassembly Buffer . . . . . . . . . . . . . . . . . . . . . 69
4.5 Internal Clock Recovery Circuit (ICRC) . . . . . . . . . . . . . . . . . . . . . . . . . . . 70
4.5.1 Data Flow . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
4.5.2 Frame Generator . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
4.5.3 Frame Receiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
4.5.4 RTS Receive FIFO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 72
4.5.5 RTS Transmit FIFO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
4.5.6 ICRC Loopback Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
4.5.7 RTS Injection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 73
4.5.8 Fractional Divider . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
4.5.9 Clocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 5 2003-01-20
4.5.10 Power Management . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
4.5.11 PLL Block . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
4.5.11.1 PLL-SRTS: . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 74
4.5.11.2 PLL-FILTER . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
4.5.11.3 PLL-ACM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75
4.5.11.4 SRTS with ACM: . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 78
4.6 Internal Queues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
4.6.1 Event Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
4.6.2 Output Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
4.6.3 Interrupt Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 79
4.7 OAM Processing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 80
4.8 Loopback Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
4.8.1 Upstream Loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
4.8.2 Downstream Loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81
4.8.3 Serial Loop . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 82
4.9 Cell Insertion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83
4.10 Cell Extraction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84
4.11 Mapping of Channels to Timeslots . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
4.11.1 ATM Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 85
4.11.2 AAL Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
4.11.2.1 Unstructured CES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 86
4.11.2.2 Structured CES . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 87
4.11.2.3 Structured CES with CAS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88
5 Interface Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
5.1 Generic Framer Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
5.1.1 FALC Mode (FAM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
5.1.1.1 T1 FALC Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
5.1.1.2 E1 FALC Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
5.1.2 Generic Interface Mode (GIM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
5.1.2.1 T1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
5.1.2.2 E1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98
5.1.3 Synchronous Modes (SYM) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100
5.1.3.1 Synchronous Mode at 2.048 MHz (SYM2) . . . . . . . . . . . . . . . . . . . 100
5.1.3.2 Synchronous Mode at 8.192 MHz (SYM8) . . . . . . . . . . . . . . . . . . . 102
5.1.4 Echo Canceller Mode (EC) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
5.2 UTOPIA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
5.2.1 Port Addresses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 105
5.2.2 Back Pressure/ATM Cell Discarding . . . . . . . . . . . . . . . . . . . . . . . . . . 106
5.2.2.1 General Backpressure Mechanism . . . . . . . . . . . . . . . . . . . . . . . . . 106
5.2.2.2 Port Specific Backpressure Mechanism . . . . . . . . . . . . . . . . . . . . . 107
5.2.3 Sideband Signals of the UTOPIA Interface . . . . . . . . . . . . . . . . . . . . . 107
5.3 IMA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 6 2003-01-20
5.4 Clock Recovery Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 110
5.5 Microprocessor Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
5.5.1 Interrupt Handling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 112
5.5.2 Microprocessor Interface Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 113
5.6 External RAM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
5.7 Boundary Scan Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 117
5.8 Master Clock . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 118
6 Memory Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
6.1 Internal Configuration RAM’s . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 120
6.1.1 RAM1: Receive Port Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . 121
6.1.1.1 RAM1: ATM Receive Reference Slot . . . . . . . . . . . . . . . . . . . . . . . 121
6.1.1.2 RAM1: ATM Receive Continuation Slot . . . . . . . . . . . . . . . . . . . . . . 122
6.1.1.3 RAM1: AAL Receive Reference Slot . . . . . . . . . . . . . . . . . . . . . . . . 123
6.1.1.4 RAM1: AAL Receive Continuation Slot . . . . . . . . . . . . . . . . . . . . . . 126
6.1.1.5 RAM1: ATM or AAL Receive Idle Slot . . . . . . . . . . . . . . . . . . . . . . . 127
6.1.2 RAM2: Transmit Port Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . 127
6.1.2.1 RAM2: ATM Transmit Reference Slot . . . . . . . . . . . . . . . . . . . . . . . 127
6.1.2.2 RAM2: ATM Transmit Continuation Slot . . . . . . . . . . . . . . . . . . . . . 128
6.1.2.3 RAM2: AAL Transmit Reference Slot . . . . . . . . . . . . . . . . . . . . . . . 129
6.1.2.4 RAM2: AAL Transmit Continuation Slot . . . . . . . . . . . . . . . . . . . . . . 132
6.1.2.5 RAM2: ATM or AAL Transmit Idle Slot . . . . . . . . . . . . . . . . . . . . . . 133
6.1.3 RAM3: Transmit Port Configuration Extended . . . . . . . . . . . . . . . . . . . 134
6.1.3.1 RAM3: AAL Transmit Reference Slot . . . . . . . . . . . . . . . . . . . . . . . 134
6.1.4 RAM4: Transmit Port Configuration Extended . . . . . . . . . . . . . . . . . . . 135
6.1.4.1 RAM4: AAL Transmit Conditioning Slot . . . . . . . . . . . . . . . . . . . . . . 136
6.2 External RAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
6.2.1 Statistics Counters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 137
6.2.2 Statistics Counter thresholds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 140
6.2.3 Interrupt Queue . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 141
6.2.4 Timers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 142
6.2.5 Cell Insertion Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 143
6.2.6 Cell Extraction Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 144
6.2.7 Segmentation/ATM Receive Buffers . . . . . . . . . . . . . . . . . . . . . . . . . . 145
6.2.7.1 ATM Receive Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 146
6.2.7.2 Segmentation Buffer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 146
6.2.8 Reassembly/ATM Transmit Buffers . . . . . . . . . . . . . . . . . . . . . . . . . . . 146
7 Register Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148
7.1 Port Configuration Registers (pcfN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151
7.2 ASIC Configuration Register (acfg) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 154
7.3 OAM Control Register (oamc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156
7.4 OAM-Counter Enable Register for ATM Ports (catm) . . . . . . . . . . . . . . . 157
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 7 2003-01-20
7.5 OAM-Counter Enable Register for AAL Ports (caal) . . . . . . . . . . . . . . . . 158
7.6 Byte-Pattern Register bp3 and bp2 (bp32) . . . . . . . . . . . . . . . . . . . . . . . 159
7.7 Byte-Pattern Register bp1 and bp0 (bp10) . . . . . . . . . . . . . . . . . . . . . . . 160
7.8 ATM Control Register (atmc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 161
7.9 RX Idle/Unassigned Cell Control Register (rxid) . . . . . . . . . . . . . . . . . . . 162
7.10 TX Idle/Unassigned Cell Control Register (txid) . . . . . . . . . . . . . . . . . . . 163
7.11 Loopback Control Register (lpbc) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 164
7.12 Cell Fill Register for Partially Filled Cells (cfil) . . . . . . . . . . . . . . . . . . . . . 165
7.13 Interrupt Mask Register 1 (imr1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 166
7.14 Timer Enable Register (time) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 167
7.15 Cell Delineation FSM Status Register (cdfs) . . . . . . . . . . . . . . . . . . . . . . 168
7.16 Version Register (vers) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 169
7.17 Clock Monitor Register (ckmo) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 170
7.18 Interrupt Status Register 1 (isr1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 171
7.19 Extended Interrupt Status 1 Register (eis1) . . . . . . . . . . . . . . . . . . . . . . . 173
7.20 Extended Interrupt Status 2 Register (eis2) . . . . . . . . . . . . . . . . . . . . . . . 174
7.21 Extended Interrupt Status 3 Register (eis3) . . . . . . . . . . . . . . . . . . . . . . . 175
7.22 Extended Interrupt Status 4 Register (eis4) . . . . . . . . . . . . . . . . . . . . . . . 176
7.23 Interrupt Status Register 2 (isr2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 177
7.24 Operation Mode Register (opmo) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178
7.25 FT Clock Select Register (ftcs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 180
7.26 Cell Filter VCI Pattern 1 Register (cfvp1) . . . . . . . . . . . . . . . . . . . . . . . . . 181
7.27 Cell Filter VCI Mask 1 Register (cfvm1) . . . . . . . . . . . . . . . . . . . . . . . . . . 182
7.28 Cell Filter VCI Pattern 2 Register (cfvp2) . . . . . . . . . . . . . . . . . . . . . . . . . 183
7.29 Cell Filter VCI Mask 2 Register (cfvm2) . . . . . . . . . . . . . . . . . . . . . . . . . . 184
7.30 Cell Filter Payload Type Register (cfpt) . . . . . . . . . . . . . . . . . . . . . . . . . . 185
7.31 Command Register (cmd) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 186
7.32 Cell Filter Read Pointer Register (cfrp) . . . . . . . . . . . . . . . . . . . . . . . . . . 187
7.33 Threshold Register (thrshld) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 188
7.34 UTOPIA Configuration Register (utconf) . . . . . . . . . . . . . . . . . . . . . . . . . 189
7.35 CAS 1 Register (cas1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 191
7.36 CAS 2 Register (cas2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 192
7.37 CAS 3 Register (cas3) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 193
7.38 Threshold Register for Ports 0 and 1 (thrsp01) . . . . . . . . . . . . . . . . . . . . 194
7.39 Threshold Register for Ports 2 and 3 (thrsp23) . . . . . . . . . . . . . . . . . . . . 195
7.40 Threshold Register for Ports 4 and 5 (thrsp45) . . . . . . . . . . . . . . . . . . . . 196
7.41 Threshold Register for Ports 6 and 7 (thrsp67) . . . . . . . . . . . . . . . . . . . . 197
7.42 Extended Interrupt Status 0 Register (eis0) . . . . . . . . . . . . . . . . . . . . . . . 198
7.43 LCD Timer Register (lcdtimer) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 199
7.44 Interrupt Source Register (irs) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200
7.45 Interrupt Mask (irm) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 201
7.46 Internal Clock Recovery Circuit Configuration Register (icrcconf) . . . . . . 202
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 8 2003-01-20
7.47 Configuration Register Downstream of Port N (condN) . . . . . . . . . . . . . . 204
7.48 Interrupt Source of Port N (irsN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 206
7.49 Interrupt Mask of Port N (irmN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 207
7.50 Test Input of Port N (tsinN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 208
7.51 Configuration Register Upstream Direction of Port N (conuN) . . . . . . . . 209
7.52 Average Buffer Filling of Port N (avbN) . . . . . . . . . . . . . . . . . . . . . . . . . . 210
7.53 ACM Shift Factor of Port N (asfN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 211
7.54 Time of Initial Free Run of Port N (tiniN) . . . . . . . . . . . . . . . . . . . . . . . . . 212
7.55 Threshold Out of Lock Detection of Port N (tresh) . . . . . . . . . . . . . . . . . . 213
7.56 ICRC Parity Errors at Clock Recovery Interface (per) . . . . . . . . . . . . . . . 214
7.57 ICRC Synchronization Errors at Clock Recovery Interface (scri) . . . . . . 215
7.58 ICRC Clock Recovery Interface FIFO Overflow (crifo) . . . . . . . . . . . . . . 216
7.59 ICRC Version Register (icrcv) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 217
7.60 SRTS Receive FIFO Underflow of Port N (sruN) . . . . . . . . . . . . . . . . . . . 218
7.61 SRTS Receive FIFO Overflow of Port N (sroN) . . . . . . . . . . . . . . . . . . . . 219
7.62 SRTS Generator Reset of Port N (srrN) . . . . . . . . . . . . . . . . . . . . . . . . . 220
7.63 SRTS Invalid Value Processed of Port N (sriN) . . . . . . . . . . . . . . . . . . . . 221
7.64 ACM Data Too Late of Port N (atlN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 222
7.65 Out Of Lock Register of Port N (oolN) . . . . . . . . . . . . . . . . . . . . . . . . . . . 223
7.66 Status Register of Port N (statN) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 224
7.67 Test Output Register of Port N (tsoutN) . . . . . . . . . . . . . . . . . . . . . . . . . . 225
8 Application Hints . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 226
8.1 Clock Concept . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 226
8.2 Translating AAL Statistics Counters into the ATMF CES Version 2 MIB . 228
8.3 Jitter Characteristics of the Internal Clock Recovery Circuit . . . . . . . . . . 230
8.3.1 ACM Jitter Tolerance in E1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 230
8.3.2 ACM Jitter Tolerance in T1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 231
8.3.3 SRTS Jitter Tolerance in E1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . 233
8.3.4 SRTS Jitter Tolerance in T1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . 234
8.3.5 ACM Jitter Transfer in E1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 236
8.3.6 ACM Jitter Transfer in T1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 237
8.3.7 SRTS Jitter Transfer in E1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 239
8.3.8 SRTS Jitter Transfer in T1 Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 240
9 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242
9.1 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242
9.2 Operating Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 243
9.3 Thermal Package Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 244
9.4 DC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 245
9.5 Capacitances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 246
9.6 AC Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 247
9.6.1 Clock and Reset Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 247
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Table of Contents Page
Data Sheet 9 2003-01-20
9.6.2 Framer Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 248
9.6.2.1 Framer Interface in FAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 248
9.6.2.2 Framer Interface in GIM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 251
9.6.2.3 Framer Interface in SYM Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . 254
9.6.2.4 Framer Interface in EC Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256
9.6.3 UTOPIA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 256
9.6.4 IMA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260
9.6.5 Clock Recovery Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 261
9.6.6 Microprocessor Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 262
9.6.6.1 Intel Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 262
9.6.6.2 Motorola Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 264
9.6.7 RAM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 265
9.6.8 Boundary-Scan Test Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 267
10 Testmode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268
10.1 Device Identification Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268
10.2 Instruction Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268
10.3 Boundary-Scan Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268
11 Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 273
12 Appendix . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274
12.1 ATM Adaptation Layer 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274
12.2 Synchronous Residual Time Stamp SRTS . . . . . . . . . . . . . . . . . . . . . . . 278
12.3 Adaptive Clock Method ACM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 280
12.4 Channel Associated Signalling . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 281
12.4.1 E1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 281
12.4.2 DS1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 282
13 Contacts for SRTS Patent Fee . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 284
14 Glossary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 285
15 Bibliography . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 288
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
List of Figures Page
Data Sheet 10 2003-01-20
Figure 1 Logic Symbol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17
Figure 2 Typical IWE8 Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18
Figure 3 Line Card for 8 T1/E1 Channels . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19
Figure 4 Echo Canceller Application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20
Figure 5 Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 22
Figure 6 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 37
Figure 7 Cell delineation state diagram (Figure 5/I.432.1) . . . . . . . . . . . . . . . . . 47
Figure 8 Maintenance state transitions for cell delineation (Figure 2/ I.432.3). . 47
Figure 9 HEC: Receiver mode of Operation (Figure 3/ITU I.432.1) . . . . . . . . . . 48
Figure 10 HEC Detection According to ATM Forum . . . . . . . . . . . . . . . . . . . . . . 49
Figure 11 Pre-assigned cell header values at the UNI (Table 1/I.361) . . . . . . . . 50
Figure 12 Pre-defined header field values [11] . . . . . . . . . . . . . . . . . . . . . . . . . . 50
Figure 13 SAR-PDU of AAL Type 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53
Figure 14 Synchronization of SRTS Generation with the Start of Segmentation. 57
Figure 15 Reassembly Buffer Initialization: No CDV . . . . . . . . . . . . . . . . . . . . . . 64
Figure 16 Reassembly Buffer Initialization: positive CDV at Start Up . . . . . . . . . 65
Figure 17 Reassembly Buffer Initialization: Negative CDV at Start Up . . . . . . . . 66
Figure 18 Reassembly Buffer Initialization for SDT: positive CDV at Start Up. . . 67
Figure 19 Block Diagram of the ICRC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 71
Figure 20 Transient Parameters . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 76
Figure 21 Influence of Damping on Lock in Time. . . . . . . . . . . . . . . . . . . . . . . . . 77
Figure 22 Connection of IWE8 to QuadFALC . . . . . . . . . . . . . . . . . . . . . . . . . . . 91
Figure 23 Framer Interface in FAM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 94
Figure 24 Framer Interface in GIM T1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97
Figure 25 Framer Interface in GIM E1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99
Figure 26 Framer Interface in SYM2 E1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 101
Figure 27 Framer Interface in SYM8 E1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103
Figure 28 Framer Interface in EC Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104
Figure 29 UTOPIA Receive and Transmit Interfaces in Slave Mode . . . . . . . . . 105
Figure 30 Utopia Sideband Signals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 108
Figure 31 IMA Interface Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 109
Figure 32 Connection of IWE8 to an Intel Type Microprocessor . . . . . . . . . . . . 113
Figure 33 Connection of IWE8 to an Motorola Type Microprocessor . . . . . . . . 114
Figure 34 External RAM Connection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 115
Figure 35 RAM Interface Protocol . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 116
Figure 36 Memory Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 119
Figure 37 Structure of the IWE8 external RAM . . . . . . . . . . . . . . . . . . . . . . . . . 137
Figure 38 Clock Concept . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 226
Figure 39 ACM Jitter Tolerance in E1 Mode without Jitter Attenuator . . . . . . . . 230
Figure 40 ACM Jitter Tolerance in E1 Mode with Jitter Attenuator . . . . . . . . . . 231
Figure 41 ACM Jitter Tolerance in T1 Mode without Jitter Attenuator . . . . . . . . 232
Figure 42 ACM Jitter Tolerance in T1 Mode with Jitter Attenuator . . . . . . . . . . 232
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
List of Figures Page
Data Sheet 11 2003-01-20
Figure 43 SRTS Jitter Tolerance in E1 Mode without Jitter Attenuator . . . . . . . 233
Figure 44 SRTS Jitter Tolerance in E1 Mode with Jitter Attenuator. . . . . . . . . . 234
Figure 45 SRTS Jitter Tolerance in T1 Mode without Jitter Attenuator . . . . . . . 235
Figure 46 SRTS Jitter Tolerance in T1 Mode with Jitter Attenuator. . . . . . . . . . 235
Figure 47 ACM Jitter Transfer in E1 Mode without Jitter Attenuator . . . . . . . . . 236
Figure 48 ACM Jitter Transfer in E1 Mode with Jitter Attenuator. . . . . . . . . . . . 237
Figure 49 ACM Jitter Transfer in T1 Mode without Jitter Attenuator . . . . . . . . . 238
Figure 50 ACM Jitter Transfer in T1 Mode with Jitter Attenuator . . . . . . . . . . . . 238
Figure 51 SRTS Jitter Transfer in E1 Mode without Jitter Attenuator . . . . . . . . 239
Figure 52 SRTS Jitter Transfer in E1 Mode with Jitter Attenuator . . . . . . . . . . . 240
Figure 53 SRTS Jitter Transfer in T1 Mode without Jitter Attenuator . . . . . . . . 241
Figure 54 SRTS Jitter Transfer in T1 Mode with Jitter Attenuator . . . . . . . . . . . 241
Figure 55 Input/Output Waveforms for AC Measurements . . . . . . . . . . . . . . . . 247
Figure 56 Clock and Reset Interface Timing Diagram . . . . . . . . . . . . . . . . . . . . 247
Figure 57 Framer Receive Interface Timing in FAM . . . . . . . . . . . . . . . . . . . . . 248
Figure 58 Framer Transmit Interface Timing in FAM . . . . . . . . . . . . . . . . . . . . . 250
Figure 59 Framer Receive Interface Timing in GIM . . . . . . . . . . . . . . . . . . . . . . 251
Figure 60 Framer Transmit Interface Timing in GIM . . . . . . . . . . . . . . . . . . . . . 252
Figure 61 Framer Interface Timing for SYM 2.048 MHz . . . . . . . . . . . . . . . . . . 254
Figure 62 Framer Interface Timing in SYM 8.192 MHz . . . . . . . . . . . . . . . . . . . 255
Figure 63 Framer Interface Timing in EC Mode. . . . . . . . . . . . . . . . . . . . . . . . . 256
Figure 64 Setup and hold time definition (single- and multi PHY) . . . . . . . . . . . 257
Figure 65 Tri-state timing (multi-PHY, multiple devices only). . . . . . . . . . . . . . . 257
Figure 66 Timing of the IMA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260
Figure 67 Clock Recovery Interface Timing Diagram . . . . . . . . . . . . . . . . . . . . 261
Figure 68 Intel Mode Write Cycle Timing Diagram . . . . . . . . . . . . . . . . . . . . . . 262
Figure 69 Intel Mode Read Cycle Timing Diagram . . . . . . . . . . . . . . . . . . . . . . 263
Figure 70 Motorola Mode Timing Diagram. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 264
Figure 71 RAM Interface Timing Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 265
Figure 72 Boundary-Scan Test Interface Timing Diagram. . . . . . . . . . . . . . . . . 267
Figure 73 Package Outline: P-BGA-256 (Plastic Metric Quad Flat Package) 273
Figure 74 Structure of the AAL1 SAR-PDU . . . . . . . . . . . . . . . . . . . . . . . . . . . . 274
Figure 75 Informative and Example Algorithm State Machine (Fig. III.2/I.363.1) 276
Figure 76 The Concept of SRTS (Fig. 5/I.363.1) . . . . . . . . . . . . . . . . . . . . . . . . 278
Figure 77 Generation of Residual Time Stamp (RTS) (Fig.6/ I.363.1). . . . . . . . 279
Figure 78 Example Multiframe Structure for 3x64 kbit/s E1 with CAS . . . . . . . . 282
Figure 79 Example Multiframe Structure for 1x64 kbit/s DS1 with CAS. . . . . . . 283
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
List of Tables Page
Data Sheet 12 2003-01-20
Table 1 Generic Framer Interface (73 pins) . . . . . . . . . . . . . . . . . . . . . . . . . . . 23
Table 2 UTOPIA Interface (36 pins) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
Table 3 IMA Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27
Table 4 Clock Recovery Interface. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Table 5 Microprocessor Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 28
Table 6 External RAM Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 30
Table 7 Test Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 31
Table 8 Miscellaneous . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32
Table 9 Power Supply. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Table 10 Not Connected Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33
Table 11 Functions of IWE8 Blocks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38
Table 12 ATM Cell Discarding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43
Table 13 Activation sequence for ATM transmit ports . . . . . . . . . . . . . . . . . . . . 45
Table 14 Activation sequence for ATM receive ports . . . . . . . . . . . . . . . . . . . . . 51
Table 15 Definition of the CAS Signalling Conditioning Nibbles. . . . . . . . . . . . . 54
Table 16 Relationship betw. Cell Filling & Segmentation Buffer Subblock Size . 55
Table 17 Cell Filling level values. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 56
Table 18 Activation sequence for AAL segmentation channels . . . . . . . . . . . . . 56
Table 19 Activation sequence for AAL reassembly channels . . . . . . . . . . . . . . . 63
Table 20 Relationship betw. Cell Filling and Reassembly Buffer Subblock Size 63
Table 21 Coding of Slot Type in internal configuration RAMs . . . . . . . . . . . . . . 85
Table 22 RAM slot positions for ITU-T G.804 compliant ATM mapping . . . . . . . 85
Table 23 AAL Idle slot positions for structured CES in AAL mode . . . . . . . . . . . 87
Table 24 AAL Idle slot positions for structured CES with CAS in AAL mode . . . 89
Table 25 Time slot Mapping in T1 Translation Mode 0. . . . . . . . . . . . . . . . . . . . 94
Table 26 F-Channel Format in T1 Mode. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95
Table 27 Clock Recovery Interface frame format . . . . . . . . . . . . . . . . . . . . . . . 110
Table 28 Configuration of the Microprocessor Interface Mode . . . . . . . . . . . . . 113
Table 29 Master Clock Frequency Depending on Mode. . . . . . . . . . . . . . . . . . 118
Table 30 Statistics Counters for ATM Ports . . . . . . . . . . . . . . . . . . . . . . . . . . . 138
Table 31 Statistics Counters for AAL Ports. . . . . . . . . . . . . . . . . . . . . . . . . . . . 138
Table 32 Internal Registers. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 148
Table 33 Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 242
Table 34 Clock and Reset Interface AC Timing Characteristics . . . . . . . . . . . . 247
Table 35 Framer Receive Interface Timing in FAM . . . . . . . . . . . . . . . . . . . . . 249
Table 36 Framer Transmit Interface Timing in FAM . . . . . . . . . . . . . . . . . . . . . 250
Table 37 Framer Receive Interface Timing in GIM . . . . . . . . . . . . . . . . . . . . . . 251
Table 38 Framer Transmit Interface Timing in GIM . . . . . . . . . . . . . . . . . . . . . 253
Table 39 Framer Interface AC Timing Characteristics in SYM2 Mode . . . . . . . 254
Table 40 Framer Interface Timing in SYM8 . . . . . . . . . . . . . . . . . . . . . . . . . . . 255
Table 41 Framer Interface Timing in EC Mode. . . . . . . . . . . . . . . . . . . . . . . . . 256
Table 42 Transmit Timing (8-Bit Data Bus, 33 MHz, Single PHY) . . . . . . . . . . 258
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
List of Tables Page
Data Sheet 13 2003-01-20
Table 43 Receive Timing (8-Bit Data Bus, 33 MHz, Single PHY). . . . . . . . . . . 258
Table 44 Transmit Timing (8-Bit Data Bus, 33 MHz, Multi-PHY) . . . . . . . . . . . 259
Table 45 Receive Timing (8-Bit Data Bus, 33 MHz, Multi-PHY) . . . . . . . . . . . . 259
Table 46 IMA Interface AC Timing Characteristics . . . . . . . . . . . . . . . . . . . . . . 261
Table 47 Clock Recovery Interface AC Timing Characteristics . . . . . . . . . . . . 261
Table 48 Intel Mode Write Cycle AC Characteristics . . . . . . . . . . . . . . . . . . . . 262
Table 49 Intel Mode Read Cycle AC Timing Characteristics . . . . . . . . . . . . . . 263
Table 50 Motorola Mode AC Timing Characteristics . . . . . . . . . . . . . . . . . . . . 264
Table 51 RAM Interface AC Timing Characteristics . . . . . . . . . . . . . . . . . . . . . 266
Table 52 Boundary-Scan Test Interface AC Timing Characteristics. . . . . . . . . 267
Table 53 Boundary Scan Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 268
Table 54 Bit allocation of E1 time slot 16 for CAS . . . . . . . . . . . . . . . . . . . . . . 281
Table 55 Allocation of CAS Bits to 24 Frame Multiframe . . . . . . . . . . . . . . . . . 283
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 14 2003-01-20
1Overview
The Interworking Element for
8 E1/T1 Lines PXB 4219E, PXB 4220E, PXB 4221E (IWE8) is a member of Infineon’s
ATM chip set. Together with framing and line interface components (e.g. Infineon’s
QuadFALC PEB 22554) the IWE8 serves as gateway between Asynchronous Transfer
Mode (ATM) networks and timeslot based PDH networks.
Each of the 8 E1 or T1 input and output ports can be configured independently to operate
in one of two basic modes:
ATM Mode
ATM mode ports operate as an ATM User Network Interface (UNI) at 2.048 Mbit/s (E1)
or 1.544 Mbit/s (T1).
The device supports mapping of ATM cells in T1/E1 frames according to ITU-T G.804,
“ATM Cell Mapping into Plesiochronous Digital Hierarchy (PDH)” [26] and ATM Forum,
“ATM on Fractional E1/T1” [9].
It implements all Transmission Convergence (TC) sublayer functions of the Physical
Layer (PHY) defined in ITU-T I.432, “B-ISDN User-network Interface - Physical layer
Specification” [32]
AAL Mode
AAL mode ports operate as an ATM Circuit Emulation Service Interworking Function
(CES-IWF) between Constant Bit Rate (CBR) equipment and an ATM network as
described by the ATM Forum, “Circuit Emulation Services Version 2.0" [10]. (only PXB
4220/4221)
The CBR circuits are converted into ATM constant bit-rate virtual channels using the
ATM Adaptation Layer type 1 (AAL1) as defined in I.363.1, “B-ISDN ATM Adaptation
Layer Specification, Types 1 and 2" [31] or without any ATM Adaptation Layer overhead,
which will be referred as AAL type 0 throughout the rest of this document.
The IWE8 provides the segmentation and reassembly function.
Both the “Unstructured DS1/E1 Service” and the “Structured DS1/E1 N x 64 kbit/s Basic
Service” as described in the “Circuit Emulation Services Version 2.0" by the ATM Forum
in [10] are supported. For simplicity reasons the shorthand notation “Unstructured CES”
will be used to identify the “Unstructured DS1/E1 Service” while the “Structured DS1/E1
N x 64 kbit/s Service” will be referred to as “Structured CES” throughout the rest of this
document.
Data Sheet 15 2003-01-20
Type Package
PXB 4219E, PXB 4220E, PXB 4221E P-BGA-256
Interworking Element for
8 E1/T1 Lines
IWE8
PXB 4219E, PXB
4220E, PXB 4221E
Version 3.4
1.1 Features
Full duplex ATM Packetizer/Depacketizer for 8 E1/T1
highways
Configurable to T1 or E1 mode via external pin
8 T1/E1 ports configurable independently to ATM or
AAL Mode
ATM Mode (PXB 4219/4220/4221):
ATM cell mapping into PDH according to ITU-
T G.804 [26]
B-ISDN User-Network interface - Physical Layer
according to ITU-T I.432 [32]
B-ISDN User-Network interface - Physical Layer operation at 1544 KBit/s and 2048
KBit/s according to ITU-T I.432.3 [34]
AAL Mode (PXB 4220/4221):
AAL1 according to ITU-T I.363.1 [31] or transparent without any adaptation layer
overhead (AAL0)
T1/E1 unstructured service according to ATM Forum af-vtoa-0078.000 [10] section
3
Structured T1/E1 N x 64 kbit/s service according to [10] section 2 with M channels
of N x 64 kbit/s (M,N = 1to 24 for T1) (M,N = 1to 32 for E1)
Channel Associated Signalling (CAS) support according to [10]
Echo Canceller Mode
Partially filled cells with programmable filling thresholds
Selectable Sequence Count Algorithm:
Robust/Fast according to ITU-T I.363.1 [30]
According to ETSI (prl-ETS 300353 annex D) [17]
Fast: Saves 6 ms during reassembly for 1 x 64 kbit/s connection
AAL0 option: 48 Bytes user payload per ATM Cell, without AAL overhead
Reassembly buffer can compensate up to +/- 4 ms Cell Delay Variation (CDV)
Statistics counters per channel for lost/misinserted/errored cells etc.
P-BGA-256-2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 16 2003-01-20
Internal clock recovery circuit using Synchronous Residual Time Stamp (SRTS, for
fully filled cells only) or Adaptive Clock Method (ACM) for unstructured CES ports.
For SRTS a patent fee needs to be paid. Optionally, it’s possible to order the PXB
4221 device, which comes without SRTS clock recovery.
Trunk freezing and conditioning according to Bellcore TR-NWT-000170 [14]
IMA interface:
Programmable threshold between read and write pointer of Mapping Buffer
Output Signal for buffer threshold crossing
Output Signal for discarded cell
Output pins for port number indication
8 generic framer interfaces with integrated transmit clock selector supporting
Synchronous Mode (SYM) for E1
Generic Interface Mode (GIM)
FALC Mode (FAM): Glue-less interface for Infineon’s Framer and Line Interface
Components (FALC)
Echo Canceller Mode (EC): ATM cells are duplicated internally and transmitted via
two framer ports
UTOPIA industry standard interface:
Level 2 in slave mode; 8 data, 5 address lines
Level 1 in master/slave mode
UTOPIA clock up to 38.88 MHz
16-bit generic microprocessor interface for control and configuration of the chip runs
either in Intel 386EX or Motorola compatible mode
External synchronous Flow-Through SSRAM 1 x 64k x 33 bit or 1 x 64k x 32 bit
required
Build-in data path loops for test
Cell insertion/extraction via microprocessor interface
3.3 Volt power supply with 5 Volt tolerant inputs
Typical power dissipation 1 Watt
P-BGA-256 package
Temperature range from -40° to +85°C
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 17 2003-01-20
1.2 Logic Symbol
Figure 1 Logic Symbol
PXB 4219
PXB 4220
PXB 4221
Framer
Interface
FRCLK[0:7]
FRFRS[0:7]
FRDAT[0:7]
FRMFB[0:7]
FRLOS[0:7]
FTCKO[0:7]
FTFRS[0:7]
FTDAT[0:7]
FTMFS[0:7]
Test Interface
OUTTR
TRST
UTTR
ITST[0:3]
TCK
TMS
TDI
TDO
MPDATA[0:15]
MPADR[0:17]
MPCS
MPWR
MPRD
MPRDY
MPIR1,2
Micro-
processor
Interface
RAM
Interface
RMADR[0:15]
RMDAT[0:32]
RMCS
RMOE
RMWR
RMCLK
RMADC
UTOPIA
Interface
(Level 2)
TXDAT[0:7]
TXADR[0:4]
TXCLK
TXPTY
TXSOC
TXCLAV
TXENB
RXDAT[0:7]
RXADR[0:4]
RXCLK
RXPTY
RXSOC
RXCLAV
RXENB
CR Interface
SSP
SDOR
SDOD
SDI
SCLK
ATBTC
PN0
UNCHEC
PN1
PN2
IMA
Interface
ILS2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 18 2003-01-20
1.3 Typical Applications
Figure 2 illustrates three typical application areas which utilize the IWE8 chip in Line
Interface Cards (LICs) or Network Interface Controllers (NICs).
Application 1 utilizes the IWE8 as an internetworking device for communication between
a narrowband Time-Slot based network and an ATM network.
Application 2 utilizes the IWE8 chip to enable the use of an existing T1/E1 access line
for connection to an ATM network.
In application 3, the IWE8 chip enables terminals using a Leased Line or Time-Slot
based service to convert from T1/E1 network connection to ATM network connection
without noticeable changes to the subscriber.
Figure 2 Typical IWE8 Applications
The PXB 4220 IWE8 chip is designed to handle up to eight T1/E1 ports. It transfers data
between the Pulse Code Modulation (PCM)-highway and an UTOPIA ATM Interface.
ATM Links
ATM
Network
ATM Links
Unstructured Circuit Emulation
Service for DS1/E1 (with/
without partially filled cells) for
Leased Lines over ATM
Structured Circuit Emulation
Service for DS1/E1
(Nx64kbit/s with/without
partially filled cells) over ATM
NNI/UNI 2.048 Mbps,
NNI/UNI 1.544 Mbps
(I.432.2, G.804)
Multiservice
Switch IWE
TM
8
Application 2
0
7
Application 3
PBX DS1/E1 Links
IWE
TM
8
PBX DS1/E1 Links
Application 1
0
7
IWE
TM
8
PBX DS1/E1 Links
PBX DS1/E1 Links
0
7
Tia
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 19 2003-01-20
1.3.1 Line Card
Figure 3 shows an example Line Interface Card (LIC) utilizing the IWE8 in a switch
environment. Two Infineon Quad Framer and Line Interface Component (QuadFALC,
PEB 22554) chips are connected at the PCM ports. An ATM Layer circuit is connected
at the UTOPIA Interface port and could be implemented using Infineon PXB 4350 ATM
Layer Processor (ALP) chip.
Figure 3 Line Card for 8 T1/E1 Channels
External synchronous SRAM is always required for proper IWE8 operation. The IWE8
requires only one main operating clock of 12 times the data rate of one port. An
emergency clock of 32.768 MHz is optional. The Framer and Utopia interface clocks can
be completely asynchronous with respect to the main clock. A microprocessor controls
and operates the IWE8 via a generic 16-bit interface.
1.3.2 Echo Canceller
In communication links reflections resulting in an electrical echo are due to hybrid splits
or imperfect terminations in subscriber loops. Acoustical echoes may occur due to poor
isolation of microphone and speaker of some telephone systems. These electrical and
acoustical echoes disturb the quality of the transmission. To ensure high quality, pure
data transmission the ITU-T suggests in the recommendation G.131 [22] the use of echo
cancellers. Echo cancellation is extremely desirable for data links with total round trip
transmission times of more than 50 ms.
QuadFALC
PEB 22554
IWE8
T1/E1
Lines
FT SSRAM
64 K x 36 Bit
ATM Layer
Circuit
e.g. ALP
PXB 4350
Clock Supply
Clock = 25 MHz
Serial
Interface
UTOPIA
Interface
Switching
Network
QuadFALC
PEB 22554
Mag.
Mag.
Lcf8tc
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 20 2003-01-20
Figure 4 Echo Canceller Application
The echo cancelling function itself is performed in STM. In the application above the
IWE8 is used to translate voice ATM channels into STM channels and vice versa.
Infineon’s Smart Integrated Digital Echo Canceller (SIDEC, PEB 20954) is used for
cancellation of the echo that is generated by reflection on the near end side and heard
by the far end speaker. The SIDEC can cancel end echo paths (SDH or PDH network
on near end side) up to 128 ms. For details see [21]
PDH
network
IWU
IWE8
PXB4220
SIDEC
PEB20954
FALC LH
PEB2255
ATM
network
Near End Far End
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Overview
Data Sheet 21 2003-01-20
1.4 Differences Between PXB4220 And PXB4219
The IWE8 type PXB 4219 does only support the ATM mode used for ITU-T G.804
compliant ATM cell mapping into the plesiochronous digital hierarchy (PDH) at line rates
of 1544 kbit/s and 2048 kbit/s. The AAL mode is not available.
1.5 Differences Between PXB4220 And PXB4221
The IWE8 type PXB 4220 uses an internal clock recovery mechanism (SRTS) which is
patented by Bellcore. SRTS is supported for fully filled cells only.
Related Patents are:
Bellcore patent No. 5,260,978
(Synchronous Residual Time Stamp for Timing Recovery in a broadband network)
Bellcore patent No. 4,839,306
(Method and apparatus for multiplexing circuit and packet traffic)
Infineon Technologies is not allowed to collect SRTS license fees on the IWE8 on behalf
of Bellcore. Contacts for license issues are given in Chapter 13.
Every IWE8 customer must get in contact with Bellcore legal department by himself to
clarify whether his application needs to license the SRTS functionality.
For customers who do not want to use the built-in SRTS mechanism, Infineon provides
a special version of the IWE8. The name of this device is PXB 4221 and covers the same
functionality (pin and register compatible) like the PXB 4220. SRTS is physically and
permanently disabled, so that no patent fees have to be paid.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 22 2003-01-20
2 Pin Descriptions
2.1 Pin Diagram
Figure 5 Pin Configuration
YWVUTRPNMLKJHGFEDCBA
YWVUTRPNMLKJHGFEDCBA
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
Ball Layout Bottom View
TXADR
_1
E1T1
MPADR
_16
MPADR
_13
MPADR
_9
MPADR
_6
MPADR
_4
MPADR
_1
PN0RFCLK
MPDAT
_15
MPDAT
_12
MPDAT
_8
MPDAT
_5
MPDAT
_2
MPWRTMSTCK
FTCKO
_4
GND
TXADR
_3
TXADR
_0
CLK52
MPADR
_15
MPADR
_12
MPADR
_8
MPADR
_5
MPADR
_2
MPIR1CLOCK
MPDAT
_13
MPDAT
_11
MPDAT
_7
MPDAT
_4
MPDAT
_1
MPCSTDO
FTCKO
_5
FTDAT
_7
FTMFS
_7
RXADR
_2
TXADR
_2
TSCENEC
MPADR
_14
MPADR
_11
MPADR
_7
MPADR
_3
MPIR2RESET
MPDAT
_14
MPDAT
_10
MPDAT
_6
MPDAT
_3
MPRDTRSTN.C.
FTFRS
_7
FRFRS
_7
FRMFB
_7
RXADR
_3
TXADR
_4
RXADR
_0
GND
MPADR
_17
VDD
MPADR
_10
GND
MPADR
_0
MPRDYVDD
MPDAT
_9
GND
MPDAT
_0
VDDTDIGND
FTCKO
_7
FRDAT
_7
FRLOS
_7
FTCKO
_6
FRCLK
_7
FTFRS
_6
FRFRS
_6
VDD
FTMFS
_6
FRMFB
_6
FRCLK
_6
FTDAT
_6
FRDAT
_6
FRLOS
_6
FTFRS
_5
GND
FTMFS
_5
FTDAT
_5
FRFRS
_5
FRMFB
_5
FRDAT
_5
FRCLK
_5
FRLOS
_5
FTFRS
_4
FTMFS
_4
FTDAT
_4
FRFRS
_4
VDD
FRMFB
_4
FRDAT
_4
TSCSH
FTMFS
_3
FTFRS
_3
FRLOS
_4
FRCLK
_4
GND
FTCKO
_3
FRFRS
_3
FRDAT
_3
FTMFS
_2
FRCLK
_3
FRDAT
_3
FRMFB
_3
VDD
FTDAT
_2
FTFRS
_2
FRLOS
_3
FRLOS
_2
FRMFB
_2
FTCKO
_2
FRFRS
_2
PN2PN1
RXADR
_4
RXADR
_1
TXDAT
_0
TXSOC
TXCLA
V
VDD
TXDAT
_3
TXDAT
_2
TXDAT
_1
TXENB
TXDAT
_6
TXDAT
_5
TXDAT
_4
GND
TXCLKUTTRTXPTY
TXDAT
_7
ATBTCRXSOC
RXCLA
V
VDD
RXDAT
_0
RXDAT
_1
RXDAT
_2
RXDAT
_3
RXDAT
_4
RXDAT
_5
RXDAT
_6
RXDAT
_7
RXPTYRXENBRXCLKGND
OUTTRRMCLK
RMDAT
_0
RMDAT
_3
PMT
RMDAT
_1
RMDAT
_4
VDD
RMDAT
_2
RMDAT
_5
RMDAT
_7
RMDAT
_9
RMDAT
_6
RMDAT
_8
RMDAT
_10
GNDSSPVDD
RMDAT
_22
GND
RMDAT
_31
VDD
RMADR
_3
RMADR
_7
GND
FRCLK
_0
VDD
FTFRS
_0
GND
FTFRS
_1
FTMFS
_1
FRDAT
_2
SDI
RMDAT
_11
TBUS
RMDAT
_16
RMDAT
_19
RMDAT
_21
RMDAT
_25
RMDAT
_28
RMDAT
_32
RMADC
RMADR
_2
RMADR
_6
RMADR
_10
RMADR
_14
FRDAT
_0
FRFRS
_0
FRLOS
_1
FRMFB
_1
FTDAT
_1
FRCLK
_2
RMDAT
_12
RMDAT
_13
RMDAT
_14
RMDAT
_15
RMDAT
_20
RMDAT
_23
RMDAT
_26
RMDAT
_29
RMWRRMOE
RMADR
_1
RMADR
_5
RMADR
_9
RMADR
_12
RMADR
_15
FRMFB
_0
FTDAT
_0
FRCLK
_1
N.C.
FRFRS
_1
SDODSDOR
RMDAT
_17
RMDAT
_18
SCLK
RMDAT
_24
RMDAT
_27
RMDAT
_30
RMCS
UNCHE
C
RMADR
_0
RMADR
_4
RMADR
_8
RMADR
_11
RMADR
_13
FRLOS
_0
FTCKO
_0
FTMFS
_0
FRDAT
_1
FTCKO
_1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 23 2003-01-20
2.2 Pin Definitions and Functions
Output Pull Up and Pull Down Type Definitions
2.2.1 Generic Framer Interface
PUx Pull Up of strength x (x = A, B) is implemented. The
corresponding current is specified in Chapter 9.4
PDx Pull Down of strength x (x = A) is implemented. The
corresponding current is specified in Chapter 9.4
Tri Tri-stated when inactive
Table 1 Generic Framer Interface (73 pins)
Pin No. Symbol Input (I)
Output (O)
Function
C5, A6, B9,
A12, C14,
A18, C19,
G17
FRCLK[7:0] I Framer Receive Clock
Receive clock for the framer interface
B4, C7, C9,
B11, B14,
A17, B20,
F18
FRDAT[7:0] I
PDA
Framer Receive Data
Receive data input of the framer interface
A3, B6, D9,
C11, A14,
C16, C18,
E19
FRMFB[7:0] I
PUA
Framer Receive Multiframe Begin
Indication that a new multi-/superframe is
available on the receive side of the framer
interface
B3, A5, A8,
A10, B13,
A16, A19,
E18
FRFRS[7:0] O
PUA
Framer Receive Frame Synchronization
Pulse
Indication that a new frame is available on
the receive side of the framer interface
A4,B7, A9,
B12, A15,
D16, D18,
E20
FRLOS[7:0] I
PDA
Framer Receive Loss of Signalling
Indication that CAS bits are invalid, IWE8
will start CAS freezing
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 24 2003-01-20
C4, D5, C2,
B1, C13,
B16, A20,
D20
FTCKO[7:0] O/I
PDA
Framer Transmit Clock
Transmit clock for the framer interface.
Recovered clock output from the ICRC
Framer receive clock output from pin
FRCLKN
Output of the clock derived from RFCLK
Input for an external clock recovery
device
B2, D7, B8,
B10, A13,
C15, B18,
D19
FTDAT[7:0] O
PUA
Framer Transmit Data
Transmit data output of the framer interface
A2, C6, C8,
C10, D12,
D14, B17,
C20
FTMFS[7:0] O
PUA
Framer Transmit Multiframe
Synchronization
Indication that a new multi-/superframe is
available on the transmit side of the framer
interface
C3, B5, A7,
D10, C12,
B15, C17,
E17
FTFRS[7:0] O
PUA
Framer Transmit Frame Synchronization
Pulse
Indication that a new frame is available on
the transmit side of the framer interface
L1 RFCLK I Reference Clock
SYM and EC mode: Central framer interface
clock for all framer ports
FAM and GIM: Optional SRTS/ACM
reference or emergency clock for the framer
receive interface in case of clock failure
Table 1 Generic Framer Interface (73 pins) (cont’d)
Pin No. Symbol Input (I)
Output (O)
Function
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 25 2003-01-20
2.2.2 UTOPIA Interface
Table 2 UTOPIA Interface (36 pins)
Pin No. Symbol Input (I)
Output (O)
Function
U12, V12,
W12, Y12,
U11, V11,
W11, Y11
RXDAT[7:0] O
PUA
UTOPIA Receive Data Bus
Byte-wide data driven from PHY to ATM
layer. RxData[7] is the MSB.
Y13 RXPTY O
PUA
UTOPIA Receive Odd Parity Bit
Odd parity for RXDAT[0:7] driven by the
PHY layer.
W10 RXSOC O
PDA
UTOPIA Receive Start-of-Cell
Active high signal asserted by the PHY layer
when RXDAT[0:7] contains the first valid
byte of a cell.
V10 RXCLAV Slave: O
Master: I
PDA
UTOPIA Receive Cell Available
Slave: RXCLAV is an active high signal
asserted by the PHY layer to indicate that it
has data available for transfer to the ATM
layer.
Master: RXCLAV is an active high signal
asserted by the ATM layer to indicate that it
has data available for transfer to the PHY
layer.
V13 RXCLK I UTOPIA Receive Clock
Transfer/synchronization clock from the
ATM layer to the PHY layer for
synchronizing transfers on RXDAT[0:7].
W13 RXENB Slave: I
Master: O
PUA
UTOPIA Receive Enable
Slave: Active low signal asserted by the
ATM layer to indicate that RXDAT[0:7] and
RXSOC will be sampled at the end of the
next cycle.
Master: Active low signal asserted by the
PHY layer to indicate that RXDAT[0:7] and
RXSOC will be sampled at the end of the
next cycle.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 26 2003-01-20
V5, Y4, Y3,
U5, V4
RXADR[4:0] I
PUA
UTOPIA Receive Address Bus
Five bit wide true data driven from the ATM
to MPHY layer to select the appropriate
MPHY device. RXADR[4] is the MSB.
U9, Y8,
W8, V8,
Y7, W7,
V7, Y6
TXDAT[7:0] I
PUA
UTOPIA Transmit Data Bus
Byte-wide true data driven from ATM to
PHY layer. TXDAT[7] is the MSB.
V9 TXPTY I
PUA
UTOPIA Transmit Odd Parity Bit
TXPTY is the odd parity bit over TXDAT[0:7]
driven by the ATM layer.
W6 TXSOC I
PDA
UTOPIA Transmit Start-of-Cell
Active high signal asserted by the ATM
layer when TXDAT[0:7] contains the first
valid byte of the cell.
V6 TXCLAV Slave: O
Master: I
PDA
UTOPIA Transmit Cell Available
Slave: TXCLAV is an active high signal
asserted by the PHY layer to indicate it can
accept data.
Master: TXCLAV is an active high signal
asserted by the ATM layer to indicate it can
accept data.
Y9 TXCLK I UTOPIA Transmit Clock
Data transfer/synchronization clock
provided by the ATM layer to the PHY layer
for synchronizing transfers on TXDAT[0:7].
Table 2 UTOPIA Interface (36 pins) (cont’d)
Pin No. Symbol Input (I)
Output (O)
Function
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 27 2003-01-20
2.2.3 IMA Interface
U7 TXENB Slave: I
Master: O
PUA
UTOPIA Transmit Enable
Slave: Active low signal asserted by the
ATM layer during cycles when
TXDAT[0:7] contains valid cell data.
Master: Active low signal asserted by
the PHY layer during cycles when
TXDAT[0:7] contains valid cell data.
W4, Y2,
W3, Y1,
W2
TXADR[4:0] I
PUA
UTOPIA Transmit Address Bus
Five bit wide true data driven from the ATM
to MPHY layer to poll and select the
appropriate MPHY device. TXADR4 is the
MSB.
Table 3 IMA Interface
Pin No. Symbol Input (I)
Output (O)
Function
Y10 ATBTC O
Tri
ATM Transmit Buffer Threshold
Crossing
Indicates if the difference between the write
and read pointer of the mapping buffer
became smaller than a SW selectable
threshold
L20 UNCHEC O
Tri
Uncorrectable HEC Error
Indicates if a cell has been discarded due to
an uncorrectable HEC error
Y5, W5,
M1
PN[2:0] O
Tri
Port Number
Indicates the port number where the cell
causing ATBT or UNCHEC being asserted
came from
Table 2 UTOPIA Interface (36 pins) (cont’d)
Pin No. Symbol Input (I)
Output (O)
Function
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 28 2003-01-20
2.2.4 Clock Recovery Interface
2.2.5 Microprocessor Interface
Table 4 Clock Recovery Interface
Pin No. Symbol Input (I)
Output (O)
Function
Y18 SDI I Serial Data Input
Clock recovery frame input.
Y20 SDOD O
Tri
Serial Data Output Data
Clock recovery frame output
W20 SDOR O
Tri
Serial Data Output Reset
Clock recovery reset frame output
T17 SSP O
Tri
Serial Synchronization Pulse
Frame synchronization pulse output
T20 SCLK O
Tri
Serial Clock
Clock output of the clock recovery interface.
Runs at the same frequency than the
CLOCK input
Table 5 Microprocessor Interface
Pin No. Symbol Input (I)
Output (O)
Function
K1, K3, K2,
J1, J2, J3,
J4, H1, H2,
H3, G1,
G2, G3, F1,
F2, G4
MPDAT[15:0] I/O
PUA
Microprocessor Data Bus
This bidirectional three-state bus provides
the general-purpose data path between the
IWE8 and an external master. The bus uses
little endian word order. MPDAT15 is the
MSB.
T4, V1, U2,
T3, U1, T2,
R3, P4, T1,
R2, P3, R1,
P2, P1, N3,
N2, N1, M4
MPADR[17:0] I Microprocessor Address Bus
Provides the address of the current bus
cycle. Addresses are 16-bit aligned.
MPADR17 is the MSB of the bus
E2 MPCS IMicroprocessor Chip Select
This signal is driven by the bus master to
indicate a read or write access.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 29 2003-01-20
E1 MPWR/
MPRW
IMicroprocessor Write Enable (Intel Bus
Mode)
This signal is driven by the bus master to
indicate a write data transfer
Read/Write Enable (Motorola Bus Mode)
This three-state signal is driven by the bus
master to indicate the direction of the bus’s
data transfer
F3 MPRD/
MPTS
IMicroprocessor Read Enable (Intel Bus
Mode)
This signal is driven by the bus master to
indicate a read data transfer
Microprocessor Transfer Start (Motorola
Bus Mode)
This signal is asserted by the bus master to
indicate the start of a bus cycle that
transfers data to or from the device
L4 MPRDY
MPTA
O
Tri
Microprocessor Ready (Intel Bus Mode)
This three-state output indicates that the
device has accepted date from the master
(write) or has driven the data bus with valid
data (read)
Microprocessor Transfer Acknowledge
(Motorola Bus Mode)
This three-state output indicates that the
device has accepted date from the master
(write) or has driven the data bus with valid
data (read)
M2 MPIR1 O
PUB
Microprocessor Interrupt Request 1
Main interrupt pin indicating a special event
in the IWE8.
M3 MPIR2 O
PUB
Microprocessor Interrupt Request 2
This signal is generated by timer set 2 to
indicate that a counter expired
Table 5 Microprocessor Interface (cont’d)
Pin No. Symbol Input (I)
Output (O)
Function
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 30 2003-01-20
2.2.6 External RAM Interface
Table 6 External RAM Interface
Pin No. Symbol Input (I)
Output (O)
Function
F19, G18,
F20, G19,
G20, H18,
H19, H20,
J17, J18,
J19, J20,
K17, K18,
K19, K20
RMADR[15:0] O
Tri
RAM Address Bus
This bus provides the address of the current
bus cycle. RMADR15 is the MSB.
M18, M17,
N20, N19,
N18, P20,
P19, P18,
R20, R19,
P17, R18,
T19, T18,
U20, V20,
U18, U19,
V19, W19,
Y19, W18,
V17, U16,
W17, V16,
Y17, W16,
V15, U14,
Y16, W15,
V14
RMDAT[32:0] I/O
PUB
RAM Data Bus
This bidirectional three-state bus provides
the data path between the IWE8 and the
external memory. RMDAT32 is parity bit,
RMDAT31 is the MSB.
M20 RMCS O
Tri
RAM Chip Select
This signal enables read or write accesses
to the external memory
L19 RMOE O
Tri
RAM Output Enable
This signal enables the outputs of the
external memory
M19 RMWR O
Tri
RAM Write Enable
This output is asserted when a write access
to the external memory
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 31 2003-01-20
2.2.7 Test Interface
L18 RMADC O
Tri
RAM Address Control
This output is asserted to indicate a valid
address on RMADR[15:0]
W14 RMCLK O
Tri
RAM Clock
Clock output for the external RAM. It runs at
the same frequency as CLOCK input
Table 7 Test Interface
Pin No. Symbol Input (I)
Output (O)
Function
D2 TDO O
Tri
Boundary Scan Test Data Output
E4 TDI I
PUA
Boundary Scan Test Data Input
C1 TCK I
PUA
Boundary Scan Test Clock
D1 TMS I
PUA
Boundary Scan Test Mode Select
0 = normal operation
1 = Enable boundary scan test mode
E3 TRST I
PDA
Boundary Scan Test Reset
V3 TSCEN I
PDA
Internal Test Pins
TSCEN and TSCSH must be low for proper
operation
A11 TSCSH
Y15 PMT PDA Internal Test Pins
00 = Intel mode
01 = prohibited
10 = prohibited
11 = Motorola Mode
V18 TBUS
Table 6 External RAM Interface (cont’d)
Pin No. Symbol Input (I)
Output (O)
Function
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 32 2003-01-20
2.2.8 Miscellaneous
W9 UTTR I
PUA
Utopia TRI-STATE
0 = tristate all Utopia outputs
1 = normal operation
Y14 OUTTR IOutput TRI-STATE
0 = tristate all outputs and disable all pull-up
and pull-down resistors
1 = normal operation
Table 8 Miscellaneous
Pin No. Symbol Input (I)
Output (O)
Function
W1 E1/T1 I
PUA
E1 or T1 Mode Select
0 = T1 mode
1 = E1 mode
U3 EC I
PUA
Echo Canceller Mode Select
0 = echo canceller mode
1 = standard mode
L2 CLOCK I Master Clock
Used to clock the core of the device
L3 RESET I
PDA
Master Hardware Reset
Asynchronous reset of all flip-flops
V2 CLK52 I 51.84 MHz SRTS Reference Clock
external reference clock for SRTS. If SRTS
mode is not used, it can be connected to VSS
Table 7 Test Interface (cont’d)
Pin No. Symbol Input (I)
Output (O)
Function
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Pin Descriptions
Data Sheet 33 2003-01-20
2.2.9 Power Supply
2.2.10 Not Connected Pins
Table 9 Power Supply
Pin No. Symbol Input (I)
Output (O)
Function
D6, D11,
D15, F4,
F17, K4,
L17, R4,
R17, U6,
U10, U15
VDD Power Supply Voltage
A1, D4, D8,
D13, D17,
H4, H17,
N4, N17,
U4, U8,
U13,U17
GND Ground
Table 10 Not Connected Pins
Pin No. Symbol Input (I)
Output (O)
Function
B19, D3 N.C. Not Connected
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 34 2003-01-20
3 Functional Description
All functional parts of the device are implemented in hardware. Configuration of the
functional blocks has to be done by software via the micro controller interface.
The IWE8 provides two independent data paths for upstream, towards the ATM network,
and downstream, from the ATM network, direction. For dedicated functional tests
loopbacks between both are available.
Each of the 8 ports connected to the data path works independent from the others. It can
be switched to ATM or AAL mode and provides access to the E1/T1 Framer at different
framer interface protocols.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 35 2003-01-20
3.1 Operating Modes
3.1.1 ATM Mode
A port that is configured to ATM mode offers ITU-T G.804 [26] compliant ATM cell
mapping into PDH frames at E1 or T1 datarates. ATM mode can be enabled via “p_atm”
in register “pcfN”.
3.1.2 AAL Mode
A port that is configured to AAL mode offers ATM Forum [10] compliant circuit emulation
services via AAL1 as defined in ITU-T I.361.1 [31]. A port N can be configured to AAL
mode via “p_atm” in register “pcfN”.
Some features of the AAL mode are controlled by the internal registers “acfg”, “caal”,
“bp32”, “bp10” and “cfil”. The features controlled by these registers are common to all
AAL ports.
Some features of the AAL mode can be controlled per port, by programming the port
configuration registers “pcfN”.
Some features of the AAL mode can be controlled per channel, by programming the
channel specific “AAL Reference Slot” in the internal configuration RAM’s (RAM1 for
receive ports, RAM2, RAM3 and RAM4 for transmit ports).
3.1.2.1 Unstructured CES Mode
A 2.048 Mbit/s (E1) or 1.544 Mbit/s (T1) bitstream is packed into ATM cells without any
framing. No alignment between octets in E1 or T1 frames and octets in the ATM cells is
done.
For this Unstructured T1/E1 Circuit Emulation Service (CES) the ATM adaptation layer
type 1(AAL1) with Unstructured Data Transfer (UDT) as defined in ITU-T I.363.1[31] is
used. The use of partially filled cells is possible.
For clock recovery the IWE8 supports the Synchronous Residual Time Stamp (SRTS)
method and Adaptive Clock Method (ACM).
SRTS is possible on channels with completely filled cells
ACM can be used on both, channels with partially and completely filled cells
A port is programmed to unstructured CES via “p_ces” in the Port Configuration Register
“pcfN”.
Per port a Segmentation Buffer with a maximum size of 16 cells and a Reassembly
Buffer with a maximum size of 256 cells is implemented in external RAM.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 36 2003-01-20
3.1.2.2 Structured CES Mode
A port is programmed for the Structured T1/E1 Nx64 kbit/s Basic Service (Structured
CES) via the port configuration register “pcfN” (“p_ces” = 0).
The structured circuit emulation service is intended to carry N of the 24 (T1) or 32 (E1)
timeslots across the ATM network.
An emulated Nx64 kbit/s circuit will be referred to as a channel throughout this
document. It is possible that several channels share the same physical interface port.
In structured CES mode neither SRTS nor ACM clock recovery is possible.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 37 2003-01-20
3.2 Functional Block Diagram
Figure 6 Block Diagram
External RAM
AAL Segmentation / AAL Reassembly Buffers
ATM Transmit / ATM Receive Buffers
Cell Insertion / Cell Extraction Buffers
Statistics Counters, Threshold Timers
To Microprocessor
Tx UTOPIA
Tx E1/T1
Framer
Receive
Interface
FR x8
RM
Octet
Receive
Processing
OR
Cell Receive
Processing /
AAL
Segmentation
CR
Framer
Transmit
Interface
FT x8
Octet
Transmit
Processing
OT
Event
Queue
EQ
Serial
Loop
SL x8
Output
Queue
OQ
RTS
Buffer
RB x8
Clock &
Reset
CK
Micro-
processor
Interface
MP
OAM
Processing
OM
Interrupt
Queue
IQ
Cell Transmit
Processing /
AAL
Reassembly
CT
Upstream/Downstream
Loop
UTOPIA
Receive
Interface
UR
UTOPIA
Transmit
Interface
UT
Internal
Clock
Recovery
Circuit
CV
External
Clock
Recovery
Interface
ICRC
Rx UTOPIA
Rx E1/T1
External
RAM
Interface
Cell Insertion
IE
Cell Extraction
JTAG
Interface
JT
Ibd2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 38 2003-01-20
3.3 Functional Block Description
Table 11 Functions of IWE8 Blocks
Block Functions
FR Framer Receive interfaces
FRCLK synchronization
8 bit serial to parallel conversion
Frame and multiframe synchronization
Timeslot counter
Timeslot assignment and channel configuration (RAM1)
OR Octet Receive processing
ATM ports:
Cell delineation
HEC check: Header error detection and correction
Cell payload de scrambling
Idle or Unassigned Cell Deletion
Statistics counter event generation
Write to ATM Receive Buffer
AAL ports:
Segmentation port de correlation
Segmentation
SN/SNP generation
SDT pointer generation
RTS value insertion
Statistics counter event generation
Write to Segmentation Buffer
OQ Output Queue
FIFO containing 256 addresses of cells to be sent to UTOPIA Receive
CR Cell Receive processing
ATM ports:
Read cells from ATM receive buffer
AAL ports:
Read cells from AAL segmentation buffer
Padding of partially filled cells
UR UTOPIA Receive interface
Cell level handshake
Mapping of framer port number into ATM header in UTOPIA level 1
mode and UTOPIA level 2 single PHY mode
Output buffer for 4 cells
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 39 2003-01-20
UL Upstream Loop
Cell loopback from Cell Receive to Cell Transmit processing
Loopback buffer for 4 cells
DL Downstream Loop
Cell loopback from UTOPIA Transmit to UTOPIA Receive
Loopback buffer for 4 cells
UT UTOPIA Transmit interface
Cell level handshake
Evaluation of framer port number from ATM header in UTOPIA level 1
mode and UTOPIA level 2 singel PHY mode
Input buffer for 4 cells
CT Cell Transmit processing
Port and channel identification
ATM ports:
Write cells to ATM transmit buffer
AAL ports:
Port and channel identification
SNP field check
SN field check
SDT pointer detection and verification
RTS value extraction
Extracting reassembly buffer filling for ACM
CAS processing
Statistics counter event generation
Insertion of dummy cells at cell loss
Write to Reassembly Buffer
Table 11 Functions of IWE8 Blocks (cont’d)
Block Functions
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 40 2003-01-20
OT Octet Transmit processing
ATM ports:
Reading octets from ATM Transmit Buffer
Cell rate de coupling: idle/unassigned cell insertion
Cell payload scrambling
HEC generation
AAL ports:
Read octets from Reassembly Buffer
Handling of Reassembly Buffer Overflow
Handling of Reassembly Buffer underflow
Reassembly Buffer initialization to compensate CDV
Synchronization of AAL1 start of structure with synchronization pulse of
framer port
Statistics counter event generation
FT Framer Transmit interfaces
FTCKO synchronization
8 bit parallel to serial conversion
Generation of frame and multiframe synchronization signals
Timeslot counter
Timeslot assignment and channel configuration (RAM2, RAM3, RAM4)
SL Serial Loop
Serial loopback from Framer Transmit to Framer Receive
OM OAM processing
Processing of OAM counter events
Interrupt queue control
Microprocessor access control to external RAM
EQ Event Queue
FIFO of 256 OAM counter events
MP Microprocessor interface
Synchronization of asynchronous microprocessor interface signals
Internal registers
Interrupt generation
RM External RAM interface
Generation of external RAM interface signals
Generation of basic RAM cycle
Access control to external RAM for different blocks
Parity generation and checking
Table 11 Functions of IWE8 Blocks (cont’d)
Block Functions
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Functional Description
Data Sheet 41 2003-01-20
CV External Clock Recovery interface
Generation of serial communication frames to external clock recovery
circuit, containing RTS values and or ACM buffer filling
Generation of synchronization for RTS generation by external clock
recovery circuit.
Reception of frames with RTS values from external clock recovery circuit
RB RTS Buffer
Buffer for 2 incoming RTS values per port
CK Clock & Reset
Clock distribution
Reset control
JT JTAG interface
Boundary Scan register
TAP controller
ICRC Internal Clock Recovery Circuit
Synchronous Residual Time Stamp SRTS
Adaptive Clock Method ACM
External
RAM
ATM Transmit Buffer
Compensate packetization delay on the PDH interface.
Maximum size of 256 ATM cells per port.
Maximum size of 64 octets per ATM cell.
ATM Receive Buffer
Maximum size of 16 ATM cells per port.
Maximum size of 64 octets per ATM cell.
Segmentation Buffer
Compensate segmentation delay in the ATM network.
1024 bytes per port (unstructured CES)
256 bytes per timeslot (structured CES)
Reassembly Buffer
Compensate the Cell Delay Variation (CDV) of the ATM network.
512 bytes per timeslot. (structured CES)
Table 11 Functions of IWE8 Blocks (cont’d)
Block Functions
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 42 2003-01-20
4 Operational Description
4.1 ATM Transmit Functions
For ports configured to ATM mode the following data flow is valid:
The Cell Transmit Processing block is responsible for:
Cell discarding
Write ATM cells except of UDF octet to ATM Transmit Buffer
The Octet Transmit Processing block is responsible for:
Reading octets from ATM Transmit Buffer
Cell rate de-coupling: idle/unassigned cell insertion
Cell payload scrambling
HEC generation
The ATM transmit functions are controlled by the internal registers “catm”, “atmc” and
“txid”. The features controlled by these registers are common to all ATM ports.
Some features of the ATM transmit functions can be controlled per port, by programming
the port specific “ATM Transmit Reference Slot” in the internal configuration RAM2
4.1.1 Operation
4.1.1.1 ATM Transmit Buffer Filling Level
The amount of buffered data in transmit direction of each port is adjustable in granularity
of bytes or cells. This allows a controlled transmission delay while maintaining a
continuous ATM cell flow. The feature is implemented using the port specific back
pressure mechanism of the UTOPIA interface (Chapter 5.2.2).
The granularity and range of filling level are set independently per port in the “p_thr_m
bits of the Port Configuration Registers (“pcfN”, see Chapter 7.1). The port specific
threshold value is defined via the corresponding Threshold Port Register (“thrspN”, see
Chapter 7.38 to Chapter 7.41)
2 Modes are supported:
Mode 1 (p_thr_m = 01B) allows the definition of threshold values in the range of 0 to
255 cells. The actual value equals the contents of thrspN.
Mode 2 (p_thr_m = 10B) allows the definition of threshold values in the range of 0 to
222 bytes. The actual value equals 53 * C + B, with C representing the 2 most
significant bits of thrspN and B representing the 6 least significant bits of thrspN.
All other values of p_thr_m will switch off this feature and reset the internal counter.
To avoid deadlock conditions, the contents of the common 8 cell UTOPIA input buffer
will always be flushed into the port specific Transmit Buffers independent from their back
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 43 2003-01-20
pressure state. This results in two side effects, which have to be taken into account for
the calculation of threshold values.
After back pressure state has been entered, up to 8 additional cells may be transferred
from the UTOPIA input buffer to the port buffer.
Before a certain cell can cause port specific back pressure, it has to traverse the
UTOPIA input buffer, resulting in a delay of 4.2 to 16.8 µs.
4.1.1.2 Cell Discarding
The discarding of cells is available for ATM ports. It can depend on
Buffer filling level and CLP (Bit 0 of the 4th ATM header octet)
Buffer filling level and CLPI (Cell Loss Priority Internal, bit 6 of the UDF octet at the
UTOPIA interface)
The bit ENB, bit 5 of the UDF octet at the UTOPIA interface, is responsible for the
decision if discarding shall base on CLP or CLPI. For bit locations see Figure 30.
The buffer threshold for discarding cells is configured by register “thrshld” and applies to
all ports.
Cells that are going to be extracted via the microprocessor interface will be ignored by
the cell discard mechanism
4.1.1.3 Cell rate de-coupling: Idle/Unassigned Cell Insertion
When the ATM Transmit Buffer of a port is empty, idle or unassigned cells are
transmitted to provide cell rate de-coupling.
Idle cells are transmitted as defined in the ITU-T I.361 [30]. Unassigned cells can be
inserted, as defined in the B-ISDN UNI and NNI physical layer generic criteria [15].
The 4 MSBs of header octet 1 and the 4 LSBs of header octet 4 are programmable in
the “prg_tx_hd” field of the TX Idle/Unassigned Cell Control Register (txid, see
Chapter 7.10). All other header bits will be 0.
Table 12 ATM Cell Discarding
ENB CLPI CLP Discarding
0x0No
0 x 1 Yes, if buffer threshold has been exceeded
10xNo
1 1 x Yes, if buffer threshold has been exceeded
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 44 2003-01-20
If idle cell insertion according to ITU-T I.361 or ITU-T I.432.1 is desired, the
“prg_tx_hd” field of “txid” should be set to 0000_0001B.
If unassigned cell insertion at the NNI or uncontrolled UNI according to ITU-T I.361 is
desired, the “prg_tx_hd” field of “txid” should be set to 0000 XXX0. For X any value is
allowed.
The payload of idle or unassigned cells consists of the same octet which is repeated 48
times. It is programmable by the “prg_tx_pl” field of the “txid” register.
For ITU-T I.432.1 compliant idle cells, the “prg_tx_pl” field of “txid” should be set to
0110_1010B.
The pre-assigned values of the information field of all unassigned cells are for further
study (ITU-T I.361 [30])
4.1.1.4 Cell Payload Scrambling
ITU-T I.432.3 [34] recommends the self-synchronizing scrambler x43+1 for payload
scrambling at E1 datarates. For T1 no scrambling is recommended, which the IWE8
supports.
The scrambler function is implemented in the device. It can be disabled per port by the
x43_scrambling bit in the “ATM Transmit Reference Slot” in RAM2.
4.1.1.5 HEC Generation
The HEC generation is implemented according to ITU-T I.432.1 [33] using the generator
polynomial x8+x
2+ x + 1. To significantly improve the cell delineation performance in
the case of bit-slips it is recommended that
the check bits are added (modulo 2) to an 8-bit pattern (coset) before being inserted
in the last octet of the header.
the recommended pattern is “0101 0101".
octet 1 GFC[3:0]/VPI[11:8] = prg_tx_hd[7:4] VPI[7:4] = 0000B
octet 2 VPI[3:0] = 0000BVCI[15:12] = 0000B
octet 3 VCI[11:4] = 0000_0000B
octet 4 VCI[3:0] = 0000BPTI[2:0] = prg_tx_hd[3:1] CLP =
prg_tx_
hd[0]
octet 5 UDF
octet 6 prg_tx_pl[7:0]
..
octet 53 prg_tx_pl[7:0]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 45 2003-01-20
the receiver must subtract (equal to add modulo 2) the same pattern from the 8 HEC
bits before calculating the syndrome of the header.
As an example, if the first 4 octets of the header were all zeros the generated header
before scrambling would be “00000000_00000000_00000000_00000000_01010101”.
The starting value for the polynomial check is 0s (binary)
The coset value is programmable in the ATM Control Register (“atmc”, see
Chapter 7.8).
4.1.2 Setup of ATM Transmit Ports
Each ATM transmit port can be configured in the “channel_mode” field of the “ATM
Transmit Reference Slot” in RAM2 to operate in “Inactive”, “Active” or “Standby” mode.
In “Inactive” mode, byte-pattern 0 “bp0” is continuously sent to the framer transmit
interface.
In “Active” mode, user cells or idle/unassigned cells are sent to the framer transmit
interface.
In “Standby” mode, only idle/unassigned cells are sent to the framer transmit interface.
When activating ATM transmit ports, it is important to follow the initialization sequence
as shown in Table 13. Step 2 must be held at least 250 µs to internally reset the ATM
transmit port. During this time the device connected to the Framer Receive Interface has
to be in normal operation allowing the IWE8 to synchronize itself on the frame pulse.
Table 13 Activation sequence for ATM transmit ports
Step pcfN.
p_tx_act
ATM Transmit Reference Slot.
channel_mode
Minimum Time
1 0 = inactive 00 = Inactive
2 1 = active 00 = Inactive 250 µs
3 1 = active 01 or 11 = Active
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 46 2003-01-20
4.2 ATM Receive Functions
For ports configured to ATM mode the following data flow is valid:
The Octet Receive Processing block is responsible for:
Cell delineation
HEC check: Header error detection and correction
Cell payload de-scrambling
Idle or Unassigned Cell Deletion
Statistics counter event generation
Write cells except of UDF octet to ATM Receive Buffer
The Cell Receive Processing block is responsible for:
Read cells from ATM Receive Buffer
The ATM receive functions are controlled by the internal registers “catm”, “atmc” and
“rxid”. The features controlled by these registers are common to all ATM ports.
Some features can be controlled per port. They were configured by programming the
port specific “ATM Receive Reference Slot” in the internal configuration RAM.
4.2.1 Operation
4.2.1.1 Cell Delineation
The cell delineation algorithm is implemented according to the ITU-T Recommendation
I.432.1 [33].
To support detection of “Out of Cell Delineation” (OCD) anomalies and “Loss of Cell
Delineation” (LCD) defect, the IWE8 generates an interrupt in eis4 (Chapter 7.22)
whenever the SYNC state is left or entered. The generation of interrupts is controllable
on a per port basis through fields in the “ATM Receive Reference Slot” of RAM1
(Chapter 6.1.1.1). It is also possible to see the current state of the cell delineation FSM
(Finite State Machine) in the Cell Delineation FSM Status Register (“cdfs”, see
Chapter 7.15).
The software can then start a timer (e.g. timer_set_1 provided by the IWE8) to establish
the LCD defect state.
As octet boundaries are available within the receive physical layer prior to cell
delineation, the cell delineation process is performed octet by octet in the HUNT state.
As long as the cell delineation is not in the SYNC state, received octets are discarded.
The ALPHA and DELTA parameters, which influence the robustness of the algorithm
against false misalignment due to bit errors (ALPHA) and false delineation in the re
synchronization process (DELTA), are programmable to values between 0 and 15 in the
ATM Control Register (atmc, see Chapter 7.8), These settings are common for all ATM
ports. ITU-T I.432.1 [33] recommends:
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 47 2003-01-20
for the Cell-based Physical Layer, ALPHA = 7 and DELTA = 8.
for the Frame-based Physical Layer, ALPHA = 7 and DELTA = 6.
for other systems, values for ALPHA and DELTA are for further study.
Figure 7 Cell delineation state diagram (Figure 5/I.432.1)
Figure 8 Maintenance state transitions for cell delineation (Figure 2/ I.432.3)
HUNT
PRESYNC
SYNC
Correct HEC
DELTA consecutive
correct HEC
ALPHA consecutive
incorrect HEC
Incorrect HEC
Bit by bit
Cell by
cell
Cell by
cell
Note - The "correct HEC" means the header has no bit error (syndrome is zero) and has not
been corrected
I432-1-Fig5
Working OCD
anomally LCD defect
note 1 note 3
note 4
note 2
note1 Triggered by state transition (Case A) due to alpha consecutive incorrect HEC´s in the cell
delineation process (Fig. 5 of ITU-T Recommendation I.432.1)
note2 Triggered by state transition (Case B) due to delta consecutive correct HEC´s in thecell delineation
process (Fig. 5 of ITU-T Recommendation I.432.1)
note3 Triggered by 50 continuous ms in the OCD anomaly maintenance state
note4 Triggered by 50 continuous ms in the cell delineation "Sync" state (Fig.5 of ITU-T Recommendation
I.432.1)"
I432-3-Fig2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 48 2003-01-20
The Loss of Cell Delineation (LCD) state is entered whenever the Out of Cell (OCD) state
is continuously active for more than an user defined period of time, ITU-T I.432.1
recommends a persistence time of 50ms.
For each port a separate timer is implemented. All timers can be enabled via the ´lcd_en´
bit in the LCD Timer Register (“lcdtimer”, see Chapter 7.43). The global preload value is
defined by the “lcd_val” bits in lcdtimer. After expiration of each timer, an “lcd_start”
interrupt is generated, indicated in the Interrupt Status Register 1 (isr1, see
Chapter 7.18) and the Extended Interrupt Status Register 0 (eis0, see Chapter 7.42).
If enabled, the timer is started at the transition from SYNC to OCD-state. After expiration
LCD state is entered. Whenever the SYNC state is entered before the timer expires, the
timer is reset.
The transition from LCD to Working state follows the same procedure. If after the LCD
state the SYNC state is entered again, the timer is started and after expiration the
maintenance state machine is in working state again. In parallel an “lcd_end” interrupt is
generated indicated in “isr1” and “eis0”. If synchronization is lost again during the timer
period, LCD state is reentered and the timer is reset.
To force resynchronization of the cell delineation process, the microprocessor can force
individual ports to enter the HUNT state, by setting the bit “go_hunt” in the corresponding
“ATM Receive Reference Slot” of RAM1 (Chapter 6.1.1.1).
4.2.1.2 HEC Check: Header Error Detection and Correction
The Header Error Control (HEC) is implemented according to the ITU-T I.432.1 B-ISDN
user-network interface - Physical layer specification [33].
According to the HEC algorithm, cells are discarded when a multi-bit header error is
detected in the Correction mode or a header error is detected in the Detection mode.
According to the HEC algorithm, cells are corrected when a single-bit error is detected
in the Correction mode.
.
Figure 9 HEC: Receiver mode of Operation (Figure 3/ITU I.432.1)
The pure HEC detection mode as recommended by the ATM Forum is selectable via bit
“a_hec_algor” in register acfg (see Chapter 7.2)
Corrrection
Mode
Detection
Mode
No error detected
(No action)
Multi-bit error
detected
(Cell discarded)
Single-bit error detected
(Correction)
Error detected
(Cell discarded)
No error
detected
(No action)
I432-1-Fig3
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 49 2003-01-20
.
Figure 10 HEC Detection According to ATM Forum
No discarding of HEC errored cells as an option is available and selectable via bit
“a_hec_mode” in the register acfg (Chapter 7.2). In this case an errored HEC is
indicated by setting the most significant bit in the UDF field at the UTOPIA receive
interface. For correct operation bit P_CELL_DIS must be cleared.
4.2.1.3 Cell Payload Descrambling
ITU-T I.432.3 [34] recommends the self-synchronizing scrambler x43+1 for payload
scrambling at E1 data rates. For T1 no scrambling is recommended.
The self-synchronizing scrambler function is implemented in the device. It can be
disabled per port by the x43_descrambling bit in the “ATM Receive Reference Slot” in
RAM1.
4.2.1.4 Idle, Physical Layer or Unassigned Cell Deletion
According to ITU-T I.361 [30], idle cells, physical layer OAM cells and cells reserved for
use by the physical layer are not passed to the ATM layer at the UNI.
Detection
Mode
Error detected
Cell discarded
No error
detected
Atmfhec
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 50 2003-01-20
Figure 11 Pre-assigned cell header values at the UNI (Table 1/I.361)
In contrast to this the ATM-Forum recommends in the User-network interface
specification that the receiving ATM entity is responsible for extraction and discarding of
unassigned and idle cells.
Figure 12 Pre-defined header field values [11]
The RX Idle/Unassigned Cell Control Register (rxid, see Chapter 7.9) can be used in
order to achieve ITU-T or ATM-Forum compliance.
The 4 MSBs of header octet 1 and the 4 LSBs of header octet 4 of the received cells to
be discarded are programmable in bits “prg_rx_hd”. All other header bits must be 0. On
top the “msk_rx_hd” field of “rxid” allows to mask all or some of these bits. The masked
bits are considered as “don’t care”.
If ITU-T I.361 compliance is desired, the “prg_rx_hd” field should be set to 0000 0001.
If only idle cells should be deleted, the “msk_rx_hd” should be set to 0000 0000.
If all physical layer cells should be deleted, the “msk_rx_hd” should be set to 1111
1110.
Octet 1 Octet 2 Octet 3 Octet 4
Idle cell identification (Notes
1 and 2)
0000/0000 0000/0000 0000/0000 0000/0001
Physical OAM cell
identification (Note 2) layer
0000/0000 0000/0000 0000/0000 0000/1001
Reserved for use of the
physical layer (Notes 1, 2
and 3)
PPPP/0000 0000/0000 0000/0000 0000/PPP1
P: Indicates the bit is available for use by the physical layer
Values assigned to these but have no meaning with respect to the fields occupying the corresponding bit
positions at the ATM layer
Notes:
1 In the case of physical layer cells, the bit in the location of the CLP indication is not used for the CLP
mechanism as specified in 3.4.2.3.2/I.150.
2 Cells having header values which are identified as idle, physical layer OAM, and reserved for use by the
physical layer are not passed to the ATM layer from the physical layer.
3 Specific pre-assigned physical layer cell header values are given in Recommendation I.432
Use Octet 1 Octet 2 Octet 3 Octet 4
invalid XXXX/0000 0000/0000 0000/0000 0000/XXX1
unassigned 0000/0000 0000/0000 0000/0000 0000/XXX0
X: Indicates “don’t care” bits
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 51 2003-01-20
For ATM Forum compliance, the “prg_rx_hd” field should be set to 0000 0000.
The “msk_rx_hd” should be set to 1111 1110. This configuration will delete all
unassigned cells.
The deletion of idle, physical layer or unassigned cells can be enabled or disabled per
port by “delete_idle_cells” in the “ATM Receive Reference Slot” of RAM1
(Chapter 6.1.1.1).
4.2.2 Setup of ATM Receive Ports
Each ATM receive port can be configured in the “channel_mode” field of the “ATM
Receive Reference Slot” in RAM1 to operate in “Inactive”, “Active” or “Standby” mode.
In “Inactive” mode, no data is accepted from the framer receive interface.
In “Active” mode, data is accepted from the framer receive interface, cells are written into
the ATM Receive Buffer and cell addresses are written into the Output Queue.
In “Standby” mode, data is accepted from the framer receive interface but no cells are
written into the ATM Receive Buffer or the Output Queue. This mode can be used to test
the cell delineation.
When activating ATM receive ports, it is important to follow the initialization sequence as
shown in Table 14. Step 2 must be held at least 250 µs to internally reset the ATM
receive port. During this time the device connected to the Framer Transmit Interface has
to be in normal operation allowing the IWE8 to synchronize itself on the frame pulse.
Table 14 Activation sequence for ATM receive ports
Step pcfN.
p_rx_act
ATM Receive Reference Slot.
channel_mode
Minimum Time
1 0 = inactive 00 = Inactive
2 1 = active 00 = Inactive 250 µs
3 1 = active 01 or 11 = Active
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 52 2003-01-20
4.3 AAL Segmentation Functions
This function implements the Convergency Sublayer for Structured Data Transfer (SDT)
and Unstructured Data Transfer as well as the Segmentation Sublayer for AAL type 1 as
described in ITU-T recommendation I.363.1 [31]. The structure of AAL1 SAR-PDU is
shown in Chapter 12.
The Octet Receive Processing block is responsible for:
Segmentation port decorrelation
Segmentation
SN/SNP generation
SDT pointer generation
RTS value insertion
Statistics counter event generation
Write to Segmentation Buffer
The Cell Receive Processing block is responsible for:
Read cells from Segmentation Buffer
Padding of partially filled cells
4.3.1 Operation
4.3.1.1 Segmentation Port Decorrelation
In synchronous systems, the microprocessor may activate a number of channels
consecutively, in phase with the segmentation period of a particular channel, causing a
large number of cells to be generated within the same 125 µs period. This would result
in a large number of cells residing in the Output Queue and increase the Cell Delay
Variation (CDV).
To avoid this, a decorrelation circuit has been implemented in the “Octet Receive
processing” (OR), that inserts a random waiting period between activation of a channel
and start of cell segmentation. This feature can be activated by setting bit “dcor” in the
“AAL Receive Reference Slot” of the channel in RAM1. Otherwise segmentation is
started as soon as the channel has been activated by the microprocessor (field
“channel_mode”)
The decorrelation circuit consists of a free-running 5-bit counter at a frequency of FCLOCK/
3360 (7.5 KHz if FCLOCK= 25 MHz) a register containing a random number (bits
“dcor_random_nr”) and a comparator. Each time an octet for this channel is received the
counter is compared with the random value. Only when both values are equal,
segmentation is started.
When using the decorrelation circuit make sure that the random number is written to the
“dcor_random_nr” field of the “AAL Receive Reference Slot” before activating the
channel with “channel_mode”
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 53 2003-01-20
In SDT mode, the cells are segmented when the first (multi) frame synchronization pulse
after segmentation start is received from the framer receive interface of that channel.
The resulting SC value and pointer field of the first cell transmitted will both be 0.
4.3.1.2 Segmentation
The segmentation and reassembly function can be programmed to use, alternatively to
the standard AAL type 1 SAR-PDU, a SAR-PDU that is referred to as AAL type 0 and
consists of 48 octets payload without any overhead. The selection is done by
programming the “AAL0” field in the “AAL Receive Reference Slot”.
AAL Type 0
Figure 13 shows the AAL type 0 SAR-PDU. It is possible to fill only part of the SAR-PDU
payload with User Information octets by programming field “part_fill” in the “AAL Receive
Reference Slot” of RAM1 to values smaller than 48.
Figure 13 SAR-PDU of AAL Type 0
AAL Type 1 SDT Structure Length
For Structured Circuit Emulation Service as defined by the ATM-Forum in “Circuit
Emulation Services Version 2.0" [10] Structured Data Transfer (SDT) is used. The
structure length used for SDT in ATM cells is:
N when frame-based SDT is selected
N x 16 when CRC multiframe-based SDT is selected for E1 ports
N x 24 when superframe-based SDT or extended superframe-based SDT is
selected for T1 ports.
The selection between frame-based or multiframe-based SDT is done by the bit
“sdt_mfs” in the “AAL Receive Reference Slot”.
4.3.1.3 Transport of the Framer Port Number
If the UTOPIA interface is configured for level 2 MPHY mode, the framer port number is
transported via the UTOPIA address bits. In UTOPIA level 1 and UTOPIA level 2 single
PHY mode the framer port number is mapped into the ATM Header (see Chapter 5.2.3).
ATM-SDU = SAR-PDUATM Header
48 octets5 octets
SAR = Segmentation & Reassembly
SDU = Service Data Unit
PDU = Protocol Data Unit
ATM Layer
Dummy FillAAL user info
N octets
Aal0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 54 2003-01-20
4.3.1.4 Transport of CAS Information
The four CAS bits for each timeslot are transported within one multiframe from the framer
to the IWE8. A signalling buffer in the internal RAM (256 x 4 x 2bit) holds the CAS bits
from the framer interface. The activation of CAS packetization can be done via “p_cas”
in the register “pcfN”.
The CAS bits will be packed in a signalling substructure after the payload of one
multiframe has been packetized.
4.3.1.5 CAS Conditioning and Freezing Upstream
Normally the framer device is responsible for signalling freezing or signalling
conditioning in case of line failure. If the framer doesn’t support the feature the IWE8 can
also fulfill the requirements according to Bellcore TR-NWT-000170 [14].
Pin “FRLOS = 1" indicates that the CAS information from the framer device is invalid and
CAS conditioning or freezing upstream is starting. This state remains active until valid
CAS bits are available indicated by “FRLOS = 0".
CAS freezing means that the last valid CAS information is repeated as long as the error
cause exists. In case of CAS conditioning for each timeslot individual CAS conditioning
nibbles are sent instead. Selection between both procedures is done by setting
“sig_cond” in the “AAL Receive Reference Slot”. If the channel bandwidth is one slot, the
signalling conditioning nibbles are defined in the field “next_slot_nr” of the “AAL Receive
Reference Slot”. If the channel bandwidth is more than one slot, the signalling
conditioning nibbles are defined in the “sig_cond_nibble” of the “AAL Receive
Continuation Slot”. In the latter case the signalling conditioning nibbles defined in the first
“AAL Receive Continuation Slot” are used for the first two slots.
Table 15 Definition of the CAS Signalling Conditioning Nibbles.
Slot Number Channel Bandwidth = 1 Slot Channel Bandwidth >= 2 Slots
1 “next_slot_nr” of the “AAL
Receive Reference Slot
“sig_cond_nibble” of the first “AAL
Receive Continuation Slot”
2 - “sig_cond_nibble” of the first “AAL
Receive Continuation Slot”
3 - “sig_cond_nibble” of the second
“AAL Receive Continuation Slot”
N - “sig_cond_nibble” of the N-1th
“AAL Receive Continuation Slot”
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 55 2003-01-20
4.3.1.6 Segmentation Buffer
The Segmentation Buffer is located in external RAM providing 256 bytes of memory for
each timeslot, totalling to 64 KB for 8 ports with 32 timeslots each. The buffer for each
timeslot consists of 4 blocks with 64 octets:
Buffer size = 8 Ports x 32 Channels x 4 Blocks x 64 Octets [1]
In unstructured CES mode, one Segmentation Buffer per port provides 16 blocks.
In structured CES mode, a Segmentation Buffer per channel with a variable capacity
depending on the number of channels and the cell filling level is automatically configured
by the IWE8. The number of memory blocks depends on the bandwidth of the channel.
Thus for structured CES with N x 64-kbit/s there are N x 4 blocks per connection. Each
channel can occupy 1, 2 or 4 block-groups (4, 8 or 16 blocks). The first block-group
defines the reference slot number of the channel. The second, third and fourth block-
groups define the number of the corresponding interface slot of the channel.
The one-to-one relationship between timeslots and groups of memory blocks allows
dynamic re-configuration of a specific channel without disturbing other channels of the
same port.
4.3.1.7 Padding Partially Filled Cells
The value, used for dummy fill of partially filled cells, is programmable in the Cell Fill
Register for Partially Filled Cells (“cfil”, see Chapter 7.12). The fill octets carry no
information and are ignored at the receiver.
Table 17 shows valid values for the cell filling level, which can be configured in the field
part_fill of RAM1: AAL Receive Reference Slot (see Chapter 6.1.1.3) and RAM2: AAL
Transmit Reference Slot (see Chapter 6.1.2.3). All other values are illegal.
Table 16 Relationship betw. Cell Filling & Segmentation Buffer Subblock Size
Cell Filling
AAL0
(octets)
Cell Filling
AAL1, no
SDT
(octets)
Cell Filling
AAL1, with
SDT
(octets)
Octets per
block
Cells per
block
Octets per
cell
25-48 25-47 25–47 64 1 64
4-24 4-24 4–24 64 2 32
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 56 2003-01-20
4.3.2 Setup of AAL Segmentation Channels
In “Inactive” mode, no data is accepted from the framer receive interface.
In “Active” mode, data is accepted from the framer receive interface, segmented and
cells are written into the Segmentation Buffers and the Output Queue.
In “Standby” mode, data is accepted from the framer receive interface but no cells are
written in the Segmentation Buffers.
In “Substitute” mode, data is accepted from the framer receive interface, but substituted
by a programmable byte-pattern selected by “subst_bpslct” in the “AAL Receive
Reference Slot”. Cells are written into the Segmentation Buffers and the Output Queue.
This mode can be used for trunc conditioning to indicate idle (bit pattern = 0x7F) or out-
of-service conditions (bit pattern = 0x1A) according to af-vtoa-0078 [10] and TR-NWT-
000170 [14]
When activating the AAL segmentation channels, it is important to follow the initialization
sequence as shown in Table 18. Step 2 must be held at least 250 µs to internally reset
the AAL channel. During this time the device connected to the Framer Receive Interface
has to be in normal operation allowing the IWE8 to synchronize itself on the frame pulse.
Table 17 Cell Filling level values
ATM Adaptation
Layer Type
Partially Filled Completely Filled
Minimum Maximum
AAL0 4 47 48
AAL1 4 46 471)2)
1) If frame based SDT without CAS is used and filling level 45, the condition band_width part_fill has to be
fulfilled for correct operation.
Multiframe based SDT without CAS should not be used.
2) non-P format, cell may have only 46 user data octets in P format
AAL1 with CAS 4+Cb3)
3) Cb: Required bytes for the CAS subblock in an ATM cell = RoundUp(N/2)
46 472)
Table 18 Activation sequence for AAL segmentation channels
Step pcfN
p_rx_act
AAL Receive Reference Slot.
channel_mode
Minimum Time
1 0 = inactive 00 = inactive
2 1 = active 00 = inactive 250 µs
3 1 = active 01 or 11 = active
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 57 2003-01-20
The RTS value stored in the RTS buffer of the port is loaded from the Internal Clock
Recovery Circuit ICRC or from the Clock Recovery Interface. A new value will be
provided by the ICRC once every cycle of 8 cells. To guarantee that the value stored in
the RTS buffer of the port is correct, the procedure indicated in Figure 14 is followed.
Figure 14 Synchronization of SRTS Generation with the Start of Segmentation
After the start of segmentation, during the 1st cycle of 8 cells, the RTS generator of the
corresponding port is reset. If an external clock recovery circuit is used, it is reset by
writing a reset frame for the corresponding port on the Clock Recovery Interface. During
this cycle a dummy RTS value is transmitted.
During the 2nd cycle of 8 cells, the IWE8 expects to receive the first valid RTS value
while transmitting a dummy RTS value.
During the following cycles of 8 cells the RTS value received in the previous cycle will be
transmitted.
The dummy RTS value is programmable with “a_dummy_srts” in the register “acfg” and
is common for all ports. It must be programmed before the a_crv_en bit in “acfg” is made
active. Otherwise the first 2 RTS values transmitted will be fixed at “0000”.
If the ICRC does not provide new RTS values to the RTS Transmit Buffer (buffer
underflow), the last received value is repeated. If too many RTS values are provided
(buffer overflow), the values in excess will be omitted and a “rts_overflow” bit in the
Extended Interrupt Status Register 2 “eis2” is set.
01234567
1st Cycle of 8 Cells;
Dummy RTS Value Transmitted
2nd Cycle of 8 Cells;
Dummy RTS Value Transmitted
3rd Cycle of 8 Cells;
1st RTS Value Transmitted
Start of
Segmentation
Reset of RTS
generator
1st RTS Value
Received
2nd RTS Value
Received
sorgwsos
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 58 2003-01-20
4.4 AAL Reassembly Functions
When AAL type 0 is enabled in the “AAL Transmit Reference Slot”, the SAR-PDU and
SAR-SDU processing is disabled.
When AAL type 0 is disabled in the “AAL Transmit Reference Slot”, the SAR-PDU
header is processed according to AAL type 1 as defined in ITU-T I.363.1 [31].
For ports configured to AAL mode the following data flow is valid:
The cell transmit processing block is responsible for:
Port and channel identification
SNP field check
SN field check
SDT pointer detection and verification
SRTS value extraction
CAS processing
Statistics counter event generation
Insertion of dummy cells at cell loss
Write to Reassembly Buffer
The octet transmit processing block is responsible for:
Read octets from Reassembly Buffer
Handling of Reassembly Buffer Overflow
Handling of Reassembly Buffer underflow
Reassembly Buffer initialization to compensate CDV
Synchronization of SDT structure with port structure
Statistics counter event generation
4.4.1 Operation
4.4.1.1 Port and Channel Identification
Before an incoming cell is processed, it is determined to which port and channel the cell
is destined. This information is retrieved from the UTOPIA interface (see Chapter 5.2.3).
4.4.1.2 Sequence Number Protection field check
When an un-correctable multi-bit error is detected the Sequence Number (SN) field of
the SAR-PDU header is declared invalid, otherwise the SN field is valid. The function can
be enabled or disabled by the bit “snp_check” in the “AAL Transmit Reference Slot”. If
disabled the SN of all incoming cells are declared valid.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 59 2003-01-20
4.4.1.3 Sequence Number field check
This function implements the sequence number processing. It can be enabled via bit
“sn_check” in the “AAL Transmit Reference Slot”. If enabled, selection can be made
between Robust and Fast Sequence Count Algorithm as defined in the ITU-T I.363.1 [31]
by “sn_fast” in the “AAL Transmit Reference Slot”. If SN check is disabled, all cells are
accepted, no cells are discarded, lost and misinserted cells are not detected.
4.4.1.4 RTS Extraction and Verification
When the clock recovery verification is enabled (“crv_en” in the “AAL Transmit
Reference Slot”), and the port is configured for SRTS (“p_rts” = 1), RTS values are
extracted and verified.
The RTS value consists of the four CSI bits of the cells with odd SC values within a cycle
of 8 cells. A RTS value is accepted as correct if the following condition is true:
The SN field is valid
Four consecutive odd SC values (1, 3, 5 or 7) were received in the previous cycle of
8 cells
Otherwise the dummy RTS-value is used.
When the start of a new cycle is detected, the RTS value of the previous cycle is written
to the ICRC.
4.4.1.5 Pointer Field Detection and Verification
When SDT is enabled (“sdt” = 1 in the “AAL Transmit Reference Slot”), it is assumed that
the channel is using Structured Data Transfer. The SAR-PDU payload is supposed to be
of the P format under the following conditions:
The SN field is valid
Even SC value (0, 2, 4 or 6)
The CSI field = 1
When the “sdt_once” bit in the “AAL Transmit Reference Slot” is set to 1, only the first
cell with CSI bit = 1 in a cycle of 8 cells is supposed to contain a P format SAR-SDU. The
other cells with CSI bit = 1 within the same cycle are treated as non-P format. This
operation is recommended by ITU-T I.363.1 [31]
In the cells that are supposed to contain a P format SAR-SDU, the pointer field is verified
and accepted under the following conditions:
The parity bit is correct as defined in the ITU-T I.363.1 [31]
The value of the offset field is between 0 and 93 or is the dummy value 127.
If an invalid pointer field (93 < pointer < 127) is detected, its content is replaced by the
dummy value (127). The SAR-SDU is processed as if it would have been received with
a dummy pointer value. The P format of the SAR-PDU payload is assumed and the first
octet of the SAR-PDU payload is not processed as user information.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 60 2003-01-20
The bit “sdt_par” in the “AAL Transmit Reference Slot” allows to disable the verification
of the parity bit in the pointer field.
For multiframe based SDT the bit “sdt_mfs” in the “AAL Transmit Reference Slot” has to
be set.
4.4.1.6 CAS Conditioning and Freezing Downstream
An internal signalling buffer holds the CAS bits. In case of buffer underflow or pointer
mismatch the IWE8 provides downstream CAS conditioning and freezing according to
Bellcore TR-NWT-000170 [14].
The selection between both is done individually for each channel via Bit “cond_en” in the
“AAL Transmit Conditioning Slot” of RAM4. Values for conditioning can be selected via
the “cond_down_nibble” bits in the same register.
The spare and alarm indication bits of the first E1 frame can be programmed by setting
bits cas0portN in the registers “cas1” and “cas2”. The CAS information of idle timeslots
can be chosen by setting bits in the register “cas3”.
4.4.1.7 Insertion of Dummy Cells at Cell Loss
Upon cell loss detection, the sequence count algorithm will insert dummy cells into the
Reassembly Buffer to maintain bit count integrity. The maximum amount of
consecutively inserted cells is 6.
These dummy cells are physically inserted when reading the Reassembly Buffer. The
Reassembly Buffer itself contains only control field in front of the payload of the next
accepted cell, indicating the amount of dummy cells to be inserted.
Inserted dummy cells are not taken into account for the ACM Reassembly Buffer filling
level calculation. This means that the buffer filling level is incorrect as long as dummy
cells are physically inserted.
The data octet used for the dummy cells is the byte-pattern selected by the “starv_bpslct”
field of the “AAL transmit reference slot” of RAM3.
4.4.1.8 Reassembly Buffer
The purpose of the Reassembly Buffer is to compensate the Cell Delay Variation (CDV)
of the ATM network.
It is located in external RAM providing 512 byte of memory for each timeslot, totalling to
128 KB for 8 ports with 32 timeslots each. The buffer for each timeslot consists of 8
memory blocks with 64 octets:
Buffer size = 8 Ports x 32 Channels x 8 Blocks x 64 Octets [2]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 61 2003-01-20
The number of memory blocks used depends on the bandwidth of the channel (N*64-
kbit/s). Thus for structured CES with N*64-kbit/s there are N x 8 memory blocks per
connection.
The one-to-one relationship between timeslots and groups of memory blocks allows
dynamic re-configuration of a specific channel without disturbing other channels of the
same port.
4.4.1.9 Handling of Reassembly Buffer Overflow
Overflow is detected when, at the moment of storing an accepted cell, the extra payload
of the new cell in the buffer would exceed the logical size of the Reassembly Buffer.
For AAL type 1 two possible actions exist:
The cell is discarded.
Re-initialization of the Reassembly Buffer as described in Chapter 4.4.2.4 is in line
with the ITU-T I.361.1 [31]
The cell is accepted but the Reassembly Buffer is automatically re-initialized.
Re-initialization is done automatically without disturbing the microprocessor.
The action chosen is determined by the “auto_reinit_of” field in the “AAL Transmit
Reference Slot” in RAM3.
When using AAL type 0, the accepted cell is considered to be a misinserted cell and
rejected.
4.4.1.10 Handling of Reassembly Buffer Underflow
An underflow period is detected when no octets are available in the Reassembly Buffer
to be passed to the framer transmit interface. During the underflow period starvation
octets are passed to the framer transmit interface and Statistics Counter 12 increments
if enabled.
For AAL type 1, the underflow is considered to be caused by an extremely late cell. The
length of the underflow period is measured by counting the number of transmitted
starvation octets, expressed as a number of starvation cells that are counted by
Statistics Counter 13 if enabled
For resolving the underflow two possibilities exist:
Manual re-initialization:
Re-initialization of the Reassembly Buffer as described in Chapter 4.4.2.4 is in line
with the ITU-T I.361.1 [31]
Automatic re-initialization:
As soon as start of underflow is detected, the Reassembly Buffer is re-initialized
without disturbing the microprocessor. Thus, the underflow status for the device is no
longer valid although the underflow condition still exists. No starvation cells due to
underflow will be inserted and counter 13 will not increment
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 62 2003-01-20
The action chosen is determined by the “auto_reinit_uf” field in the “AAL Transmit
Reference Slot” in RAM3.
For AAL type 0 the detection of an underflow period is considered to be the detection of
cell loss. For this reason a dummy cell is inserted. The inserted dummy cell must be
reflected in the buffer filling level of the Reassembly Buffer.
4.4.1.11 Synchronization of SDT Structure with Port Structure
In normal operation the “ATM start of structure” is synchronized with the “Port start of
structure”. Since this synchronization may get lost, the coincidence of both events is
monitored. If they do mismatch, a two bit error counter is incremented. Upon reaching a
programmable threshold, the Reassembly Buffer is re-initialized and Statistics Counter
14 is incremented if enabled. The threshold value is programmed in the “sdt_oos_nr”
field of the “AAL Transmit Reference Slot” in RAM2. If the Statistics Counter 14 should
reflect “atmfCESPointerReframes” as defined in [10], “sdt_oos_nr” should be set to
“00”.
To compensate cell loss the Sequence Count algorithm inserts dummy cells filled with
starvation octets. In case the cell filling level is 46 octets or less, the bit count integrity
won’t be violated as the length of the AAL-user information within one SAR-SDU is
always the same. When operating with a cell-filling of 47 octets, the AAL-user
information maybe 47 octet in case of non-P format or 46 octet in case of P format SAR-
PDU. As the information on the lost cell’s SAR-PDU format is not available, it is possible
that an excess of starvation octets is transmitted. As a result, the “ATM start of structure”
might be out of phase with the “Port start of structure”.
The following procedure is implemented for re-synchronization:
At the end of expanding a burst of dummy cells a flag is set, indicating that a phase
shift might occur. The maximum phase shift is 2 octets (e.g. 2 cells with pointers are
lost within a sequence of eight cells)
When an “ATM start of structure” is received and a positive phase shift is detected
lower than or equal to 2 octets, an equal number of octets is deleted in the
Reassembly Buffer and the flag is reset.
When the detected phase shift is larger than the allowed value or negative the flag is
reset and the Reassembly Buffer is re-initialized.
When no phase shift is detected the flag is reset.
4.4.2 Setup
4.4.2.1 Setup of Reassembly Channels
Each AAL transmit channel can be configured in the “channel_mode” field of the “AAL
Transmit Reference Slot” to operate in “Inactive”, “Standby” or “Active” mode.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 63 2003-01-20
In “Inactive” mode, no cells are accepted from the “UTOPIA Transmit interface”, and
byte-pattern 0 is sent to the framer transmit interface.
In “Standby” mode, cells are accepted from the “UTOPIA Transmit interface”, but byte-
pattern 0 is sent to the framer transmit interface.
In “Active” mode, cells are accepted from the “UTOPIA Transmit interface”, and user
data octets are sent to the framer transmit interface.
When activating the AAL reassembly channels, it is important to follow the initialization
sequence as shown in Table 19. Step 2 must be held at least 250 µs to internally reset
the AAL channel. During this time the device connected to the Framer Transmit Interface
has to be in normal operation allowing the IWE8 to synchronize itself on the frame pulse.
4.4.2.2 Physical Reassembly Buffer Size
Based on the cell filling level, AAL type and use of SDT, a memory block can be divided
into subblocks, where the user data octets of a single cell are stored. The size of the
memory subblock per Reassembly Buffer is automatically adapted. Table 20 shows this
relationship.
The physical Reassembly Buffer size used for a N x 64 kbit/s connection is given by:
Physical Size(octets) = N x 8 x Cell Filling x Cells per Block. [3]
Table 19 Activation sequence for AAL reassembly channels
Step pcfN.
p_tx_act
AAL Transmit Reference Slot.
channel_mode
Minimum Time
1 0 = inactive 00 = Inactive
2 1 = active 00 = Inactive 250 µs
3 1 = active 01 or 11 = Active
Table 20 Relationship betw. Cell Filling and Reassembly Buffer Subblock
Size
Cell Filling
AAL0
(octets)
Cell Filling
AAL1, no
SDT
(octets)
Cell Filling
AAL1, with
SDT
(octets)
Octets per
block
Cells per
block
Octets per
cell
33–48 32–47 31–47 64 1 64
17–32 16–31 15–30 64 2 32
9–16 8–15 7–14 64 4 16
4–8 4–7 4–6 64 8 8
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 64 2003-01-20
4.4.2.3 Initialization of the Reassembly Buffer
Before a channel is activated, the Reassembly Buffer must be configured properly to
compensate Cell Delay Variation (CDV).
In order to avoid buffer underflow due to large cell distances the amount of initial
starvation octets that are passed to the framer interface upon arrival of the first cell needs
to be set. On the other hand this number needs to be as small as possible to avoid
excessive delay. The logical Reassembly Buffer size can be adjusted in order to detect
too small cell distances by Reassembly Buffer overflow.
All parameters are defined in the “AAL Transmit Reference Slot” in RAM3. The amount
of starvation octets given to the framer transmit interface after arrival of the first cell is
defined by “starv_ini”. The contents of the starvation octets can be defined by
“starv_bpslct” and the logical Reassembly Buffer size can be configured with “buff_lsize”.
The following sections give an overview on the Reassembly Buffer operation and
initialization.
Unstructured Data Transfer:
After activation of a channel both SAR Receiver and Framer Transmit Interface start
operation. As long as no reassembled cell is available in the Reassembly Buffer it is
considered to be in underflow condition and starvation octets are passed to the Framer
Transmit Interface.
As soon as the first reassembled cell is available in the Reassembly Buffer the device
starts building up the Reassembly Buffer threshold level. This is done by passing an
additional amount of starvation octets to the framer Transmit Interface
Figure 15 Reassembly Buffer Initialization: No CDV
Reassembly Buffer
Filling Level [octets]
Time
T
0
T
0
+T T
0
+2*T
0
4
Example:
part_fill = 16 octets
N = 16
no CDV
Time
Framer
Interf.
T
S
: (starv_ini+1) * 125µs / N
T: Average cell distance
Starvation octets
Data octets
T
0
+T
S
T
0
: First cell arrival time
buff_lsize
Reassembly Buffer no CDV
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 65 2003-01-20
As the transmission of the reassembled cell stream is delayed by “starv_ini”+1 octets,
there will be “starv_ini”+1 octets of the previous cell left in the Reassembly Buffer if the
following cell arrives without CDV.
If the maximum positive CDV is the same as the maximum negative CDV the expectation
interval has a length of 2 x CDV. Assuming N octets of data are transmitted within one
frame period of 125µs the amount of data transmitted in this interval is:
[4]
The worst case for buffer underflow is given if the first cell has maximum positive CDV.
Figure 16 Reassembly Buffer Initialization: positive CDV at Start Up
In this case the amount of starvation octets inserted after receipt of the first cell has to
be bigger than the amount of data transmitted during the expectation interval. Otherwise
the Reassembly Buffer will enter underflow condition at any time a cell with maximum
positive CDV is followed by a cell with maximum negative CDV.
[5]
The worst case for buffer overflow is given if the first cell has maximum negative CDV
and then any cell with maximum negative CDV is followed by a cell with maximum
positive CDV.
2CDV×N
125µs
---------------×=
Reassembly Buffer
Filling Level [octets]
Time
T
0
T
0
+T T
0
+2*T
0
4
Time
Framer
Interf.
T
S
: (starv_ini + 1) * 125µs / N
T: Average cell distance
Starvation octets
Data octets
T
0
-CDV+T
S
T
0
: First cell arrival time (theoretical)
Example: part_fill = 16 octets; N = 16
1st cell has max. pos. CDV = 15,625µs
2nd cell has max. neg. CDV = -15,625µs
T
0
-CDV T
0
+T+CDV T
0
+2*T-CDV
buff_lsize
Reassembly Buffer pos CD
V
starvini 1–2CDV×N
125µs
---------------×10=
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 66 2003-01-20
Figure 17 Reassembly Buffer Initialization: Negative CDV at Start Up
If the first cell has maximum negative CDV there will be “starv_ini” + 1 octets left in the
Reassembly Buffer when the following cell arrives with maximum negative CDV. In case
the following cell arrives with maximum positive CDV it will be “starv_ini” + 1 plus the
amount of data to be transmitted in the expectation interval. Just after cell arrival the
filling level of the Reassembly Buffer is at its maximum:
[6]
The delay introduced by the Reassembly Buffer is:
[7]
Structured Data Transfer:
After activation of a channel both SAR Receiver and Framer Transmit Interface start
operation. As long as no reassembled cell in P format is accepted the Reassembly Buffer
it is considered to be in underflow condition and starvation octets are passed to the
Framer Transmit Interface.
After that, “starv_ini” + 1 starvation octets are given to the Framer Transmit Interface.
Then, the transmitter reads as many octets from the Reassembly Buffer as indicated by
the pointer field. For each octet one starvation octet is given to the Framer Transmit
Interface. The next octet to be read from the Reassembly Buffer is the “ATM Start of
Structure” (The octet where the AAL1 pointer field points at).
Reassembly Buffer
Filling Level [octets]
Time
T
0
T
0
+T T
0
+2*T
0
4
Time
Framer
Interf.
T
S
: (starv_ini + 1) * 125µs / N
T: Average cell distance
Starvation octets
Data octets
T
0
+CDV+T
S
T
0
: First cell arrival time (theoretical)
Example: part_fill = 16 octets; N = 16
1st cell has max. neg. CDV = 15,625µs
2nd cell has max. pos. CDV = -15,625µs
T
0
+CDV T
0
+T-CDV T
0
+2*T+CDV
buff_lsize
Reassembly Buffer neg CD
V
bufflsize partfill starvini 1 partfill 4 CDV×N
125µs
---------------×+=+++
delay starvini 125µs×
N
------------------------------------------=
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 67 2003-01-20
After that, starvation octets are passed to the Framer Transmit Interface until the “Port
Start of Structure” is detected. A “Port Start of Structure” occurs when the Framer
Transmit Interface requests the first time-slot octet belonging to the channel in the frame
or the multiframe.
From that moment on, the “ATM Start of Structure” and “Port Start of Structure” are
synchronous and the contents of the Reassembly Buffer are passed to the framer
transmit interface.
The worst case for buffer underflow is given, if the first cell has maximum positive CDV,
the contents of the pointer field is “0” and the “Port Start of Structure” occurs right after
the transmission of “starv_ini” + 1 starvation octets.
Figure 18 Reassembly Buffer Initialization for SDT: positive CDV at Start Up
In this case the amount of starvation octets inserted after receipt of the first P format cell
has to be bigger than the amount of data transmitted during the expectation interval as
defined in (4). Otherwise the Reassembly Buffer will enter underflow condition at any
time a cell with maximum positive CDV is followed by a cell with maximum negative CDV.
[8]
The worst case for buffer overflow is given, if the first P format cell has maximum
negative CDV, the contents of the pointer field is at its maximum value Pmax and the
“Port Start of Structure” occurs right before the receipt of that P format cell. In that case
the complete frame needs to be stored in the Reassembly Buffer
Reassembly Buffer
Filling Level [octets]
Time
T
0
T
0
+T T
0
+2*T
0
4
Time
Framer
Interf.
T
S
: (starv_ini + 1) * 125µs / N
T: Average cell distance
Starvation octets
Data octets
T
0
-CDV+T
S
T
0
: First cell arrival time (theoretical)
Example: part_fill = 16 octets; N = 16
1st cell has max. pos. CDV = 15,625µs
2nd cell has max. neg. CDV = -15,625µs
T
0
-CDV T
0
+T+CDV T
0
+2*T-CDV
buff_lsize
Port Start of Structure
ATM Start of Structure
Reassembly Buffer pos CDV structur
starvini 12CDVN××
125µs
---------------------------------=–10
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 68 2003-01-20
If the first cell has maximum negative CDV there will be “starv_ini” + 1 octets left in the
Reassembly Buffer at any time a cell with maximum positive CDV is followed by a cell
with maximum negative CDV. the following cell arrives with maximum negative CDV. In
case the following cell arrives with maximum positive CDV it will be “starv_ini” + 1 plus
the amount of data to be transmitted in the expectation interval. Just after cell arrival the
filling level of the Reassembly Buffer is at its maximum:
To allow CDV compensation and SDT structure synchronization, the logical size should
be programmed to a minimum value given by:
[9]
[10]
with FR being the number of frames in a structure:
FR = 0: when SDT is not used
FR = 1: for frame based SDT
FR = 16: for multi-frame based SDT in E1 mode
FR = 24: for multi-frame based SDT in T1 mode
Pmax is the maximum number of payload octets from the pointer field to the start of
structure:
Pmax = N x FR, if N x FR < 2 x part_fill
Pmax = 2 x part_fill, if N x FR > 2 x part_fill
The logical Reassembly Buffer size is limited by its physical size. The relation is given by:
[11]
where
S = 0: in case of Fast Sequence Count Algorithm
S = 1: in case of Robust Sequence Count Algorithm
When the robust SC algorithm is used, the decision on cell acceptance is delayed until
the next cell is received. As the cell is temporarily stored in the Reassembly Buffer, there
must always be space for that cell. Therefore, the physical size of the Reassembly Buffer
must be at least the logical size plus one cell.
In the fast SC algorithm the intermediate storage of a cell is not required. The cell is
stored immediately in the Reassembly Buffer, when accepted.
The delay introduced by the Reassembly Buffer is:
[12]
bufflsize partfill starvini 1 FR N Pmax+×++++
bufflsize partfill 4 CDV×N
125µs
---------------×FR N Pmax+×++
bufflsize 8 N partfill cellsperblock S partfill××××
starvini 125µs×
N
------------------------------------------ delay starvini FR N P+×max+()125µs×
N
---------------------------------------------------------------------------------------------
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 69 2003-01-20
4.4.2.4 Re-Initialization of the Reassembly Buffer
For re-initialization of the Reassembly Buffer by the microprocessor, the processor has
to set the “mcp_reinit” bit in the “AAL Transmit Reference Slot” in RAM2, wait for 1.5
frames and reset “mcp_reinit”.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 70 2003-01-20
4.5 Internal Clock Recovery Circuit (ICRC)
The Internal Clock Recovery Circuit (ICRC) may generate RTS values in upstream
direction and a 8.192, 2.048 or 1.544 MHz transmit clock in downstream direction. Each
port works independently using its own set of control registers and error counters. The
Cell delay variation is assumed to be less than +/- 4 ms.
According to ITU-T 432.1 [33] SRTS clock recovery is only defined for unstructured CES.
Therefore, ports supporting SRTS clock recovery have to be configured for only one
channel in unstructured CES with completely filled ATM cells.
The ICRC supports two Framer Interface formats
FALC Mode (FAM, see Chapter 5.1.1) with a transmit clock frequency of 8.192 MHz
for both E1 and T1.
Generic Interface Mode (GIM, see Chapter 5.1.2) with a transmit clock frequency of
2.048 MHz in case of E1 and 1.544 MHz in case of T1.
These modes can be selected via bits “om” in the Operation Mode Register (opmo, see
Chapter 7.24) and bit “gim” in the Internal Clock Recovery Circuit Configuration Register
(“icrcconf”, see Chapter 7.46).
Transmit clocks are generated by internal PLLs based on SRTS, ACM or both. The
method of transmit clock generation is selected via bits "srt" and "acm" in the
Configuration Register Downstream of Port N ("condN", see Chapter 7.47). Generation
of RTS values is enabled via bit “rtsg” in the Configuration Register Upstream of Port N
(“conuN”, see Chapter 7.51). If ACM is used, the corresponding RTS generator can be
kept disabled.
For communication between the ICRC and the rest of the chip a frame based protocol is
used. The internal interface as well as its protocol is the same as defined for the external
clock recovery interface (see Chapter 5.4).
The ICRC contains the following sub blocks:
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 71 2003-01-20
Figure 19 Block Diagram of the ICRC
4.5.1 Data Flow
In transmit direction the ICRC generates RTS values for each port independently and
writes them into the RTS Transmit FIFO.
Received RTS values are written to the port specific RTS Receive FIFO to compensate
cell delay variation. RTS values for each port are processed at a frequency equal to the
SRTS period (8 cells). ACM values are processed immediately by the corresponding
PLL.
4.5.2 Frame Generator
This block generates 32-bit control frames that are used for communication with the rest
of the system.
For synchronization with the system the received synchronization signal PDSYN is used.
However, if this signal can’t be extracted from the received bit stream by the frame
receiver, the frames are generated by means of an internal synchronization counter.
The frame output is put in tristate during power down of the internal interface. As soon
as the internal synchronization counter is synchronized on PDSYN signal, the frame
output is enabled.
Loopback 1
RTS
32.768 MHz
2.43 MHz
Receive
Line
Clock
Transmit
Line
Clock
RTS
Buffer Filling
(ACM)
CLK52
RFCLK
SDI
SDOR
SDOD
SCLK
PDSYN
0
1
1
0
lgc
lc8
1
0
lptu
lptd
1
0
PLL
0
1
1
0
lpcr
lgs
Frame
Generator
Frame
Receiver 1
Frame
Receiver 2
RTS
Transmit
FIFO
Fractional
Divider
RTS
Receive
FIFO
RTS
generation
Microprocessor Interface, Test and Control
0
1
ena
rtsi
rtso
ena
0
1
lpru
0
1
lprd
PLL
SRTS
PLL
FILTER PLL
ACM
0
1
Clock
Recover
y
Interfac
e
2.43 MHz
Bdoti
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 72 2003-01-20
4.5.3 Frame Receiver
This block is implemented twice. Once for SRTS and ACM data via port SDOD and once
for the “reset SRTS logic” command via port SDOR.
The frame receiver is synchronized to the received synchronization signal PDSYN by
means of an internal synchronization counter. In case no sync signal is received, frames
are synchronized to the counter. The synchronization between PDSYN and the internal
counter is checked each time PDSYN is received. A synchronization error is indicated
via bit “scri” in the Interrupt Source Register (“irs”, see Chapter 7.44) at the start of a
series of wrong synchronized frames. Synchronization errors are counted and the
internal synchronization counter is synchronized on the new received synchronization
pulse. An errored frame (parity error) is indicated via bit “per” in “irs” but processed as a
normal frame.
In case the internal interface to the ICRC is switched off by the system, SCLK keeps
working. The ICRC detects the following errors:
Parity error: Because SDOD and SDOR are continuously high, the odd parity is
violated.
Synchronization error: Because PDSYN is continuously low, synchronization is not
possible.
For ACM, the Reassembly Buffer filling level is measured in number of octets and
passed to the ICRC each time a accepted cell is stored in the Reassembly Buffer.
The arrival time between 2 ACM data values is verified. The assumed maximum CDV is
4 ms. The maximum cell distance without CDV is 0.276 ms for T1 and 0.221 ms for E1.
In case the next ACM data value is not arrived within 10 ms, an error indicated in register
“atlN” is generated.
4.5.4 RTS Receive FIFO
This block is implemented for each port.
The RTS Receive FIFO compensates the Cell Delay Variation (CDV), the delay of the
system interface with it's FIFO and the phase difference between reading and writing of
the RTS Receive FIFO. Each RTS Receive FIFO provides space for 8 RTS values. After
reaching the initial filling level of 5 RTS values, delay variations of +3 / -5 RTS values
can be compensated. This corresponds to a maximum CDV of -4.4 / +7.3 ms (E1) or -
5.8 / +9.7 ms (T1).
In case of overflow (register “sroN”) or underflow (register “sruN”) the PLL-SRTS is put
in free running mode and the FIFO is restarted. These events are indicated in the SRTS
Receive FIFO Underflow Register (sruN, see Chapter 7.60) and the SRTS Receive
FIFO Overflow Register (sroN, see Chapter 7.61).
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 73 2003-01-20
In case of SRTS the PLL start-up is delayed until 5 RTS values are received. This will
take 7.3 ms for E1 and 9.7 ms for T1. During this time PLL-SRTS is free running (and bit
“frr” of register “statN” is set).
If the PLL block does not use RTS values (bit “srt”=0 in register “condN”) or the port is in
power down mode (bit “pwd”=1 in register “condN”) no data is written to this FIFO. In
case bit “ena” of register “tsinN” is set, a value from the SRTS Receive FIFO is read by
reading register “tsout”.
In cases where the network clocks of RTS generator and RTS receiver have a frequency
offset, the SRTS algorithm will generate a service frequency with the same frequency
offset. The rate of RTS value generation and consumption depends on the service
clocks. In this special case, the rate of RTS value consumption is different from the rate
of RTS value generation. Enabling the ACM algorithm will not help as the FIFO is read
by the clock generated by PLL-SRTS. As a result the SRTS Receive FIFO will generate
regular (every 20 minutes) under- or overflows.
4.5.5 RTS Transmit FIFO
Each RTS generator stores the RTS value and its port number in the RTS Transmit
FIFO. When the frame generator starts generating a new frame, it reads from the FIFO
the source address and the next RTS value.
4.5.6 ICRC Loopback Modes
Loopbacks are available for each port and for the system interface of the circuit.
Each port has 2 loopbacks. The first, situated near the framer, performs a loopback on
the clock signals. It is controlled by the bit “lgc” in the Configuration Register
Downstream Direction of Port N (condN, see Chapter 7.47), which sends the generated
clock back to the RTS generator, and “lc8” in “condN”, which sends the received clock
back to the framer interface. The second has the same internal structure. It allows to
send received RTS values of all ports back to the RTS Transmit FIFO (“lpcr”=1 in register
“condN”). Thus, this loop has a variable delay with a guaranteed maximum of RTS
Transmit FIFO depth x Frame-period. If “lgs”=1 in register “condN”, generated RTS
values are sent via the receive FIFO to the PLL.
Another loopback block is situated at the clock recovery interface. It is controlled by the
bits “lptd”, “lptu”, “lprd” and “lpru” in the ICRC configuration register “icrcconf”. Not all loop
back possibilities of this block carry useful data, but the parity can always be tested.
4.5.7 RTS Injection
In case bit “ena” of the Test Input of Port N register (tsinN, see Chapter 7.50) is set, the
RTS Transmit FIFO receives a new RTS value from field “rtsi” of “tsinN” at the moment
the microprocessor writes data to that register. RTS values coming from the RTS
generator of port N are ignored in this case. RTS values coming from the clock recovery
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 74 2003-01-20
interface and which have to be returned because of loopback “lpcr”, have priority over
register “tsinN”.
During this test, the clock recovery or, in case of loopback, the receive FIFO receives the
RTS values written in field rtsi. It is advisable to power down the circuit(s) which do not
work properly with these RTS values via bit “pwd” of “condN”. If “srt” in “condN” is reset,
the output of the RTS Receive FIFO is not used by PLL-SRTS.
4.5.8 Fractional Divider
The fractional divider generates a 2.43 MHz clock from the 51.84 MHz clock provided via
the CLK52 pin. This is done by selecting 3 out of 64 clock pulses of 51.84 MHz. The
resulting 2.43 MHz clock contains jitter components of 810 kHz and above, with a
maximum peak to peak jitter of 19 ns.
4.5.9 Clocks
For an overview on the required clocks for the ICRC please refer to Chapter 8.1.
4.5.10 Power Management
Different Power down modes are available for the ICRC:
for each port via bit “pwd” in “condN”
for the Clock Recovery Interface via bit “pdcri” in “icrcconf”.
for the complete ICRC by means of the “a_icrc_dwn” bit in the “acfg”. This feature
reduces the power consumption by approximately 50 mW. Once the ICRC is switched
off, it can only be enabled by hardware reset of the whole device.
4.5.11 PLL Block
This block is implemented for each port. It consists of 3 PLLs: PLL-SRTS, PLL-ACM and
PLL-FILTER.
The bits “srt” and “acm” in the register “condN” define, which PLL is connected to PLL-
FILTER and used for clock recovery. Each PLL may be used exclusively or in
combination.
4.5.11.1 PLL-SRTS:
PLL-SRTS is used for clock recovery using the SRTS method. It has a cut-off frequency
of 20 to 50 Hz.
The phase detector of PLL-SRTS has a linear range which optimized for jitter tolerance
requirements. It is defined by a “window” of accepted RTS values. Each time PLL-SRTS
detects values, which fall out of the window, or processes invalid values, it is forced in
hold over for 1 SRTS period, bit “hov” of register “statN” is set and the
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 75 2003-01-20
SRTS Invalid Value Processed Counter (“sriN”, see Chapter 7.63) is incremented. In
case the number of out of window conditions during 16 SRTS periods exceeds the value
given by field “tr_srts” of register “treshN”, an out of lock message, indicated with bit “ols”
of register “oolN” is generated. During start-up of the RTS Receive FIFO, PLL-SRTS is
free running and bit “frr” of register “statN” is set.
4.5.11.2 PLL-FILTER
The PLL “PLL-FILTER” has a very low cut off frequency and a tuning range of ±240 ppm.
It reduces jitter which is generated in, or passed through PLL-SRTS. Although PLL-
FILTER is placed behind PLL-ACM, it has little or no functionality in case of ACM, as
PLL-ACM has a lower cut off frequency.
If more out of lock detections during 16 SRTS periods are detected than defined with
“tr_filt” in “tresh”, an out of lock message, indicated by bit “olf” of register “oolN”, is
generated.
4.5.11.3 PLL-ACM
The PLL-ACM is a control system with feedback of 2nd order. Its phase is adjusted
according to the filling level of the Reassembly Buffer.
The average buffer filling level as defined in bits “avb” in the Average Buffer Filling
Register (“avbN”, see Chapter 7.52) is subtracted from the current buffer filling level.
The result is amplified in order to adjust the cut off frequency and to define the system’s
damping (number of bytes, needed to drive the DCO over its tuning range. The loop gain
is programmed in the ACM Shift Factor Register (asfN, see Chapter 7.53). Although
adjustable, the PLL-cut-off frequency is generally less than 1 Hz. In conjunction with a
low pass filter, CDV is very small.
The behavior of the PLL is characterized by rise time and lock in time. The rise time is
the time when the clock output enters the predefined tuning range for the first time. The
lock in time is defined as the time after which the clock stays within the accepted
deviation.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 76 2003-01-20
Figure 20 Transient Parameters
The tuning range of the DCO is limited to the value programmed to bits “tur” in register
“condN”. If the phase detector requests a higher frequency deviation the DCO enters
out-of-range condition. In this case the DCO’s output will be clipped and bit “max” of
register “statN” will be set. If the number of out-of-range conditions during 16 ATM cells
exceeds the value given by field “tr_acm” of register “treshN”, an out-of-lock message,
indicated via field “ola” of register “oolN”, is generated.
Increasing the loop-gain reduces the damping of the PLL-ACM. This will reduce the rise
time but results in overshoot and long lock-in times.
Reducing the loop-gain increases the damping. This results in lower cut off frequencies,
and prevents overshoot. Thus, CDV is less likely to drive the PLL out of lock. The rise
and lock-in time are increased. If the loop-gain is too low, the amount of bytes required
to drive the DCO over it's tuning range could cause a data buffer over- or underflow.
Optimized damping allows minimum lock-in time without overshoot. In this case PLL-
ACM’s frequency is moving asymptotically to the correct value.
Tr Tp Tl
t
2d Mp
Tr, Tr1: Rise time
Tp: Peak time
Tl: Lock in time
Mp: Peak overshoot
2d: Tuning range
f
0
: Target frequency
1
0.9
0.1
Tr1
f/f
0
ACM Transient Parameter
s
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 77 2003-01-20
Figure 21 Influence of Damping on Lock in Time
PLL-ACM tries to keep the number of bytes in the Reassembly Buffer at the average
buffer filling value programmed to register “avbN”. This value should be equivalent to the
number of bytes stored in the Reassembly Buffer during start-up, as defined by the value
programmed in the “starv_ini” field of the “AAL Transmit Reference Slot” in RAM3.
During start-up and restart, PLL-ACM will be free running for 8 x tiniN[tini] x TData as
programmed in the Time of Initial Free Run Register (“tiniN”, see Chapter 7.54). During
this time the data buffer is filled with an initial number of bytes. As tiniN[tini] is 2 bit longer
than “stav_ini” in the AAL Transmit Reference Slot of RAM3 it is possible to choose a
longer-than-necessary initialization time, to compensate start-up time differences.
After the initial free run, PLL-ACM will start locking in. The lock in time depends on:
The difference between the initial number of bytes in the data buffer (see “starv_ini” of
the “AAL Transmit Reference Slot” in RAM3) and the value programmed in register
“avbN”.
The damping, which is influenced by register “asfN”.
The maximum allowed frequency deviation given by “tur” of register “condN”.
The required frequency deviation.
0.1
1
dh
dl: low damping
dh: high damping
do: optimized damping
f/f
0
t
dl
do
Tr(dl) Tr(do) = Tl(do) Tr(dh) = Tl(dh)
ACM Edge response
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 78 2003-01-20
During this lock-in process, the output frequency might temporarily reach the
programmed minimum or maximum value. This strongly depends on the initial difference
of the data buffer filling from the value given by “avbN”.
As re-initialization of the data buffer is not reported to the ICRC, PLL-ACM will detect a
huge difference between data buffer filling and the value given by “avbN”. As a result the
output frequency will be driven to it's lowest allowed value and stays there for a relative
long period of time. For this reason it is important to program the field “tur” in register
“condN” with the smallest possible value.
4.5.11.4 SRTS with ACM:
The combination of SRTS and ACM is used when the derived network clock of the SRTS
generator differs from the derived network clock of the SRTS receiver. The maximum
difference is relatively small (+/-4.6 ppm) and should be compensated by ACM. In this
case the shifting of the difference between ACM data and register “avbN”, as
programmed in register “asfN”, has to be reduced. Stable operation of PLL-ACM in
parallel with PLL-SRTS can not be guaranteed if the shifting is not reduced. The cut off
frequency of PLL-ACM has to be much lower than the cut off frequency of PLL-SRTS,
as these PLLs are working in parallel in this case. This will also reduce the effects of
CDV, because the cut off frequency of PLL-ACM is reduced. The tuning range (register
“condN”, field “tur”) can not be reduced as PLL-ACM has to compensate jitter which is
generated by or passed through PLL-SRTS.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 79 2003-01-20
4.6 Internal Queues
4.6.1 Event Queue
All the functional blocks that process octets or cells can generate counter events, i.e.
commands to increment a particular counter in the external RAM. All counter events are
written in a FIFO queue that can store 256 counter events.
A counter event contains the statistics counter address in external RAM and an
increment value.
4.6.2 Output Queue
When a cell is completely stored in the ATM Receive or Segmentation Buffer, it is ready
to be transmitted to the ATM layer over the UTOPIA receive interface. The external RAM
address of the cell is stored in a common Output Queue (OQ).
The Output Queue is a First In First Out (FIFO) queue with a maximum of 256 cell
address entries. It is common to ATM and AAL mode ports.
As long as the Output Queue is not empty, the Cell Receive processing (CR) will write
the corresponding cell from external RAM to the UTOPIA Receive interface (UR).
4.6.3 Interrupt Queue
The Interrupt Queue in external RAM is handled as a FIFO which is written whenever a
counter reaches its threshold value.
When there are interrupts in the Interrupt Queue, the “iq_ne” bit in the interrupt status
register 1 “isr1” will be set to 1. When the corresponding bit is not masked in the “imr1”
register an interrupt will be generated on the MPIR1 pin.
The microprocessor should react on the interrupt by reading the Interrupt Queue. When
“oam_act” is set to 1, the MPADR(12:1) address bits are don’t care. The next Interrupt
Queue entry will automatically be provided.
Each Interrupt Queue entry identifies a particular OAM counter that has reached its
threshold value. The counter is identified by its “port_nr”, “channel_nr” and “counter_nr”.
When the microprocessor reads the counter value and the “dest_read” bit of the register
oamc is set to 1, the counter is automatically reset.
Each Interrupt Queue entry also indicates whether there are still more interrupts in the
queue in the “iq_ne” field of the interrupt status register “isr1”. This allows the software
to read the Interrupt Queue until it is empty without having to read the interrupt status
register “isr1” again.
When the statistics function is disabled (oamc[oam_act] = 0), the µP can read and write
all addresses of the Interrupt Queue.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 80 2003-01-20
4.7 OAM Processing
The OAM processing block (OM) will read Statistics Counter events from the Event
Queue as long as the Event Queue is not empty. The OM will read the Statistics Counter
value “count_value” and the Statistics Counter threshold from external RAM. If the
Statistics Counter is not yet at its maximum value 4000 0000H, the value is increased
with the increment value given by the counter event. If the Statistics Counter threshold
is active (“thres_act” = 1) and the Statistics Counter equals or exceeds the threshold
value “thres_value”, the OM block will write an interrupt entry in the Interrupt Queue in
external RAM. The new Statistics Counter value with indication whether an interrupt was
generated in the “int_gen” field will finally be written into external RAM.
The “dest_read” bit determines whether a read operation from the microprocessor in the
Statistics Counter address space in external RAM causes a reset of the Statistics
Counter value.
The OM block can be disabled via bit “oam_act” in the OAM control register (“oamc”, see
Chapter 7.3).
In normal operation, counter event processing should be activated (oam_act = 1). In this
case the microprocessor can only read indirectly in the Interrupt Queue.
For RAM test and initialization, the “oam_act” should be set to 0. In this mode, the
microprocessor can write and read the complete external RAM.
The use of the Statistics Counter thresholds allows the software to reduce the number
of generated interrupts and to decide at what error level an interrupt should be
generated.
When the software wants to use polling mode, the thresholds can be made inactive, and
no interrupts will be generated. The software will read all the Statistics Counters on
regular time intervals in this mode.
A combination of both methods is also possible, all the Statistics Counters are read and
reset on regular time intervals. However thresholds can be used as an extra guard: a
Statistics Counter that reaches an exceptionally high value will cause an interrupt.
For a detailed list of all implemented Statistics Counters refer to Chapter 6.2.1. For
information how to translate Statistics Counters into the ATM Forum CES MIB as defined
in [10] refer to Chapter 8.2.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 81 2003-01-20
4.8 Loopback Modes
4.8.1 Upstream Loop
The Upstream Loop block (UL) allows cells that are received at the Framer Interface and
forwarded to the UTOPIA Receive Interface to be send back via the UTOPIA Transmit
Interface to the Transmitter Interface. The UL block contains a buffer of 4 ATM cells.
To activate the Upstream Loop, the “p_ulp” bit in the Port Configuration Register (pcfN,
see Chapter 7.1) must be set to 1.
When a cell is available in the UL buffer, the UTOPIA transmit interface will de-assert the
TXCLAV signal, to prevent the ATM layer component from sending cells during the
processing of the loopback cell.
For ATM mode ports, all cells are looped regardless of their header. The loop is always
transparent allowing looped cells to be visible on the UTOPIA receive interface.
For AAL mode ports, it is possible to make a single channel loop using a VCI filter. When
the “vci_flt_ulp” bit in the Loopback Control Register (lpbc, see Chapter 7.11) is set to 0
all cells are looped. When the bit is set to 1, only those cells with the 5 LSB bits of the
VCI matching the “vci_val_ulp” field of the “lpbc” register will be looped. Loopback can
be switched from transparent to non-transparent by setting the “tulp” bit in the “lpbc
register. If the loopback is non-transparent, looped cells are not visible on the UTOPIA
receive interface.
4.8.2 Downstream Loop
It is possible to loop ATM cells that are coming in on the UTOPIA transmit interface to
the UTOPIA receive interface through the Downstream Loop (DL) block. The DL block
contains a buffer of 4 ATM cells.
When a cell is available in the DL buffer and in the Output Queue, the UTOPIA receive
interface will transmit cells from both buffers with alternating priority.
To activate the downstream UTOPIA loop, the “p_dlp” bit in the Port Configuration
Register (pcfN, see Chapter 7.1) must be set to 1.
When the downstream UTOPIA loopback is active for at least one port, the UTOPIA
transmit interface will only assert the RxCLAV signal to 1 when a free space of one ATM
cell is available in both the DL buffer and the UT input buffer.
The loopback can be made transparent or non-transparent by setting the “tdlp” bit in the
Loopback Control Register (lpbc, see Chapter 7.11). If the loopback is made non-
transparent, the looped cells are not transferred to the “Cell Transmit Processing” block
CT.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 82 2003-01-20
4.8.3 Serial Loop
The framer transmit clock, data, framesync and multi-framesync signals can be looped
from the Framer Transmit Interface to the Framer Receive Interface per port. This
feature can be enabled by setting the “p_slp” bit in the Port Configuration Register (pcfN,
see Chapter 7.1).
The loopback can be made transparent or non-transparent by setting the “tslp” bit in the
Loopback Control Register (lpbc, Chapter 7.11). If the loopback is made transparent, all
transmitted data is also visible on FTDAT. Otherwise, if non-transparent, all 1s are
transmitted on FTDAT.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 83 2003-01-20
4.9 Cell Insertion
This block allows the insertion of predefined cells stored in the Cell Insertion Buffer into
the UTOPIA receive cell stream.
The Cell Insertion Buffer, located in external RAM, offers space for one ATM cell. The
ATM cell except of the UDF octet needs to be written to the Cell Insertion Buffer via the
Microprocessor interface. When transferring the cell to the UTOPIA receive interface an
UDF of 00H will be inserted.
Cell insertion is activated by setting the bit “insert_cell” in the Command Register (“cmd”,
see Chapter 7.31) the cell is then read from the Cell Insertion Buffer and forwarded to
the UTOPIA Receive Interface.
The port number is generated randomly. Depending on the UTOPIA mode selection, it
will be mapped either on the UTOPIA address bus or in the ATM header
(“mapping_mode” = 2, 3, 4 or 5 in register “utconf”) overwriting the predefined values.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 84 2003-01-20
4.10 Cell Extraction
Cells coming in downstream direction from the UTOPIA Transmit Interface can be
extracted to the Cell Extraction Buffer instead of the Reassembly/ATM Transmit Buffer.
The Cell Extraction Buffer offers space for 254 ATM cells. It is located in the external
RAM.
Incoming cells are written to the Extraction Buffer if
their VCI matches to a pattern predefined in the Cell Filter VCI Pattern 1 Register
(cfvp1, see Chapter 7.26) where each bit of the VCI can be masked via the Cell Filter
VCI Mask Register 1 (cfvm1, Chapter 7.27)
or their VCI matches to a pattern predefined in the Cell Filter VCI Pattern 2 Register
(cfvp2, see Chapter 7.28) where each bit of the VCI can be masked via the Cell Filter
VCI Mask Register 1 (cfvm1, Chapter 7.29)
or their PTI matches to one of two pattern defined in the Cell Filter Payload Type
Register (“cfpt”, see Chapter 7.30) each of these patterns can also be masked via
“cfpt”.
Once a cell has been extracted to the cell Extraction Buffer, it is indicated by the bit
“cf_fifo_n_empty” in the Extended Interrupt Status Register (“eis1”, see Chapter 7.19).
Cells can be read with the help of the read pointer (“rdptr”) in the Cell Filter Read Pointer
Register (“cfrp”, Chapter 7.32). The rdptr can have values between 02H and FFH. This
value is a pointer to the current base-address, at which the microprocessor can read the
next extracted cell from the Extraction Buffer.
MPADR = 26000H+20
H· rdptr [13]
RMADR = 03000H+10
H· rdptr [14]
After reading the cell the rdptr has to be incremented by the microprocessor and written
back. If the rdptr is incremented to its maximum value FFH the value 02H has to be
written back instead.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 85 2003-01-20
4.11 Mapping of Channels to Timeslots
The two LSB bits of a slot entry identify the slot type:
4.11.1 ATM Mode
The IWE8 supports any mapping scheme of ATM cells into N of the 32 timeslots of the
framer interfaces.
The mapping scheme is defined by programming 32 slot positions in the internal RAMs.
RAM1 is used for receive port configuration and RAM2 for transmit port configuration.
For each configuration exactly one timeslot should be programmed as the “ATM
Reference Slot”.
Depending on the Link data rate 29 (E1) or 23 (T1) timeslots should be programmed
as “ATM Continuation Slots”.
The remaining unused slots should be programmed as “AAL Idle Slots”.
For mapping of ATM cells in T1/E1 frames according to ITU-T G.804 [26] the internal
RAM slot positions should be programmed as shown in Table 22.
Table 21 Coding of Slot Type in internal configuration RAMs
Slot Type Bit 1 Bit 0
ATM/AAL Idle 0 0
ATM/AAL Continuation 1 0
ATM/AAL Reference X 1
Table 22 RAM slot positions for ITU-T G.804 compliant ATM mapping
RAM E1 T1 in FAM T1 in GIM
Slot Slot RAM Slot Type Slot RAM Slot Type Slot RAM Slot Type
0 0 ATM Idle ATM Idle 1 ATM Continuation
1 1 ATM Reference 1 ATM Reference 2 ATM Reference
2 2 ATM Continuation 2 ATM Continuation 3 ATM Continuation
3 3 ATM Continuation 3 ATM Continuation 4 ATM Continuation
4 4 ATM Continuation ATM Idle 5 ATM Continuation
5 5 ATM Continuation 4 ATM Continuation 6 ATM Continuation
6 6 ATM Continuation 5 ATM Continuation 7 ATM Continuation
7 7 ATM Continuation 6 ATM Continuation 8 ATM Continuation
8 8 ATM Continuation ATM Idle 9 ATM Continuation
9 9 ATM Continuation 7 ATM Continuation 10 ATM Continuation
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 86 2003-01-20
However, it is possible to define other ATM cell mappings, e.g. ATM cells in less than 32
64 kbit/s channels. However, RAM slot 1 has always to be defined as Reference Slot.
4.11.2 AAL Mode
4.11.2.1 Unstructured CES
For unstructured CES according to ATM-Forums CES Specification [10] there is only
one channel per port. Therefore, the internal configuration RAMs 1 to 3 have only to be
10 10 ATM Continuation 8 ATM Continuation 11 ATM Continuation
11 11 ATM Continuation 9 ATM Continuation 12 ATM Continuation
12 12 ATM Continuation ATM Idle 13 ATM Continuation
13 13 ATM Continuation 10 ATM Continuation 14 ATM Continuation
14 14 ATM Continuation 11 ATM Continuation 15 ATM Continuation
15 15 ATM Continuation 12 ATM Continuation 16 ATM Continuation
16 16 ATM Idle ATM Idle 17 ATM Continuation
17 17 ATM Continuation 13 ATM Continuation 18 ATM Continuation
18 18 ATM Continuation 14 ATM Continuation 19 ATM Continuation
19 19 ATM Continuation 15 ATM Continuation 20 ATM Continuation
20 20 ATM Continuation ATM Idle 21 ATM Continuation
21 21 ATM Continuation 16 ATM Continuation 22 ATM Continuation
22 22 ATM Continuation 17 ATM Continuation 23 ATM Continuation
23 23 ATM Continuation 18 ATM Continuation 24 ATM Continuation
24 24 ATM Continuation ATM Idle ATM Idle
25 25 ATM Continuation 19 ATM Continuation ATM Idle
26 26 ATM Continuation 20 ATM Continuation ATM Idle
27 27 ATM Continuation 21 ATM Continuation ATM Idle
28 28 ATM Continuation ATM Idle ATM Idle
29 29 ATM Continuation 22 ATM Continuation ATM Idle
30 30 ATM Continuation 23 ATM Continuation ATM Idle
31 31 ATM Continuation 24 ATM Continuation ATM Idle
Table 22 RAM slot positions for ITU-T G.804 compliant ATM mapping (cont’d)
RAM E1 T1 in FAM T1 in GIM
Slot Slot RAM Slot Type Slot RAM Slot Type Slot RAM Slot Type
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 87 2003-01-20
programmed with one Reference Slot at RAM slot 0. This slot number is used to identify
the channel (“channel_nr” = 0).
4.11.2.2 Structured CES
For AAL ports with structured CES (Nx64 kbit/s) service, the timeslots are grouped into
channels containing N of 32 timeslots. The mapping of the N x 64 kbit/s channels into an
T1/E1 frame is done by programming the 32 positions of the internal configuration RAMs
(RAM1 for receive ports, RAM2 and RAM3 for transmit ports).
It is possible to define more than one channel of N timeslots within one frame. In this
case each channel has its own reference slot, followed by N-1 continuation slots.
Additional unused frame slots that do not belong to any channel should be programmed
as “AAL Idle Slot”.
The timeslot in the group of N timeslots with the lowest frame slot number is called the
reference slot. The corresponding frame slot position in the internal RAM should be
programmed as an “AAL Reference Slot”. The slot number of the AAL Reference Slot is
used to identify the channel (“channel_nr”).
The other frame slot positions of the channel should be programmed as “AAL
Continuation Slots”. The reference slot number, as defined by the “ref_slot_nr” field
entry, is used to identify the channel the continuation slot belongs to. The N timeslots of
a channel do not need to have consecutive frame slot numbers. They can be deliberately
chosen out of the 32 frame slots.
Table 23 AAL Idle slot positions for structured CES in AAL mode
Slot number E1 T1 in FAM T1 in GIM
0 AAL Idle AAL Idle AAL Ref./Cont./Idle
1 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
2 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
3 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
4 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
5 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
6 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
7 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
8 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
9 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
10 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
11 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
12 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 88 2003-01-20
The channel mapping can be dynamically reconfigured without disturbing other active
channels of the same port.
Note: If frame based SDT without CAS is used and filling level 45, the condition
band_width part_fill has to be fulfilled for correct operation.
Multiframe based SDT without CAS should not be used.
4.11.2.3 Structured CES with CAS
If a port is used for structured CES with CAS, additional signalling is inserted into the
channel overhead. The associated RAM slots, 0 in T1 mode and RAM slots 0 and 16 in
E1 mode, need to be configured as reference slots with “sdt_mfs” = 1.
Please note, that all settings of the AAL Reference Slot refer to the channel payload.
Therefore, in case of T1 mode in FAM or E1 mode the channel has to be set to inactive
(“channel_mode” = 0) with no bandwidth assigned (“band_width” = 0).
13 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
14 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
15 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
16 AAL Idle AAL Idle AAL Ref./Cont./Idle
17 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
18 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
19 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
20 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
21 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
22 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
23 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
24 AAL Ref./Cont./Idle AAL Idle AAL Idle
25 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
26 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
27 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
28 AAL Ref./Cont./Idle AAL Idle AAL Idle
29 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
30 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
31 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
Table 23 AAL Idle slot positions for structured CES in AAL mode (cont’d)
Slot number E1 T1 in FAM T1 in GIM
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 89 2003-01-20
In T1 mode in GIM things are different. RAM slot 0 may also be used for user data, with
“channel_mode” and “band_width” set according to the requirements of the user data
carried via that slot.
Table 24 AAL Idle slot positions for structured CES with CAS in AAL mode
Slot number E1 T1 in FAM T1 in GIM
0 AAL Reference
“channel_mode” = 0
“band_width” = 0
“sdt_mfs” = 1
AAL Reference
“channel_mode” = 0
“band_width” = 0
“sdt_mfs” = 1
AAL Reference
“sdt_mfs” = 1
1 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
2 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
3 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
4 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
5 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
6 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
7 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
8 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
9 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
10 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
11 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
12 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
13 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
14 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
15 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
16 AAL Reference
“channel_mode” = 0
“band_width” = 0
AAL Idle AAL Ref./Cont./Idle
17 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
18 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
19 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
20 AAL Ref./Cont./Idle AAL Idle AAL Ref./Cont./Idle
21 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
22 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Operational Description
Data Sheet 90 2003-01-20
23 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Ref./Cont./Idle
24 AAL Ref./Cont./Idle AAL Idle AAL Idle
25 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
26 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
27 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
28 AAL Ref./Cont./Idle AAL Idle AAL Idle
29 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
30 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
31 AAL Ref./Cont./Idle AAL Ref./Cont./Idle AAL Idle
Table 24 AAL Idle slot positions for structured CES with CAS in AAL mode
Slot number E1 T1 in FAM T1 in GIM
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 91 2003-01-20
5 Interface Description
5.1 Generic Framer Interface
The selection of the Echo Canceller mode is done via an external pin (Pin EC = 0).
In standard mode (Pin EC = 1), 4 sub modes can be selected via the “om” bits in the
Operation Mode Register (“opmo”, see Chapter 7.24)
FALC mode (FAM)
Generic Interface mode (GIM)
Synchronous mode with an external reference clock of 8 MHz (SYM8)
Synchronous mode with an external reference clock of 2 MHz (SYM2)
Depending on the level of the E1/T1 pin FAM and GIM can run based on E1 or T1
frames. SYM2 and SYM8 will always use E1 frame formats.
A clock selector for the Framer transmit clock is integrated in the IWE8. Depending on
bits “ftckn” in the FT Clock Select Register (“ftcs”, see Chapter 7.25) selection between
the following clocks is done:
the line clock FRCLK
the SRTS regenerated clock from internal or external clock recovery circuit
the clock derived from the external reference clock (pin RFCLK).
The data on the Generic Framer Interface is structured in frames repeated every 125µs.
Each frame is divided into timeslots, where the least sigificant slot is transmitted first. The
data bits in each slot are transmitted starting with the most significant bit.
5.1.1 FALC Mode (FAM)
The IWE8 can be directly connected to Infineon’s “Framer and Line interface
components” (FALC) as shown in Figure 22.
Figure 22 Connection of IWE8 to QuadFALC
QuadFALC
TM
SCLKR
RDO
SYPR
RMFB
XMFS
SYPX
XDI
SCLKX
FREEZE
IWE8
FRCLKn
FRDATn
FRMFBn
FTMFSn
FTDATn
FTCKOn
FRLOSn
FTFRSn
FRFRSn
Coitf
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 92 2003-01-20
The data is transferred between the FALC and the IWE8 via a system internal highway.
FRCLK[7:0] Framer Receive Clock
Receive system clock of 8.192 MHz (falling)
FRDAT[7:0] Framer Receive Data
FRDAT is sampled in the middle of the bit period on the falling
edge of FRCLK
FRMFB[7:0] Framer Receive Multiframe Begin
Depending on bits “p_ces” in “pcfN”:
0 = Structured CES: A pulse on this pin designates the
first frame of a new multiframe
1 = Unstructured CES: Unused
FRMFB is always sampled with the falling edge of FRCLK. If the
framing is incorrect, the IWE8 stays in hunt mode.
FRFRS[7:0] Framer Receive Frame Synchronization Pulse
FRFRS is generated at the beginning of timslot 1 of each frame
FRLOS[7:0] Framer Receive Loss of Signalling
FTCKO[7:0] Framer Transmit Clock
depending on bits ftckn in ftcs:
00 = depending on bit “rts_eval” in “opmo”:
0 = Transmit clock input with 8.192 MHz (falling)
1 = Clock of ICRC is used as transmit clock and is
also switched to FTCKO pins (FTCKO is output
pin)
01 = FRCLK (“rts_eval” = 1)
10 = Clock derived from RFCLK(“rts_eval” = 1)
11 = No clock (“rts_eval” = 1)
FTDAT[7:0] Framer Transmit Data
FTDAT is clocked with the falling edge of FTCKO:
FTMFS[7:0] Framer Transmit Multiframe Synchronization
Depending on bit p_ces in pcfN:
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 93 2003-01-20
The receive system clock and transmit system clock are both 8.192 MHz, and may be
independent from each other. The data rate is 2048 Mbit/s. This means that each bit lasts
for 4 clock cycles.
Data on the system internal highway is structured in frames of 256 bits every 125 µs. It
is transmitted in 32 slots numbered from 0 to 31 with slot 0 transmitted first. The data bits
of a slot are numbered from 1 to 8. The first transmitted bit ‘bit 1’ is the most significant
bit. Figure 23 shows the bit ordering.
0 = Structured CES: Depending on “p_tx_mfs” in
“pcfN”:
0 = Double frame mode: FTMFS is asserted every
2 frames (250 µs)
1 =
E1 CRC multiframe mode: FTMFS is asserted
every 16 frames (2 ms)
T1 mode: every 3 ms
T1 superframe mode: every 1.5 ms
1 = Unstructured CES: Unused, constant low level
FTFRS[7:0] Framer Transmit Frame Synchronization Pulse
FTFRS is generated at the beginning of timslot 1 of every frame
RFCLK Reference Clock
Reference clock for the internal clock recovery circuit
Depending on p_rx_em in pcfN: Optional emergency clock if
no transition on FRCLK is detected within 23 CLOCK cycles.
The segmentation continues using the RFCLK divided by four,
and using the byte-pattern programmed to a_emg_bpslct in
acfg for the cell payload.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 94 2003-01-20
Figure 23 Framer Interface in FAM
5.1.1.1 T1 FALC Mode
In T1 mode (Pin E1/T1 = 0) there is one F-channel carrying the F-bit (Frame Alignment
Signal/Data Link (FS/DL)) and 24 data channels numbered from 1 to 24. When using the
QuadFALC in translation mode 0 (See QuadFALC data sheet) these channels are
mapped into the 32 frame slots as shown in Table 25
.
Table 25 Time slot Mapping in T1 Translation Mode 0
Frame slot T1 channel Frame slot T1 channel
0 F channel (FS/DL) 16
1 channel 1 17 channel 13
2 channel 2 18 channel 14
3 channel 3 19 channel 15
420
5 channel 4 21 channel 16
6 channel 5 22 channel 17
7 channel 6 23 channel 18
824
FRCLKn
FRDATn
FRFRSn
FTFRSn
Framer Receive Interface:
Framer Transmit Interface:
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7B8
timeslot 31 timeslot 0 timeslot 1
FTCKOn
FTDATn
FTMFSn
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7B8
timeslot 31 timeslot 0 timeslot 1
249 250 251 252 253 254 255 256
249 250 251 252 253 254 255 256248
248 12345678910
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
11 12 13 14 15 16
FRMFBn
Fifam
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 95 2003-01-20
The F-channel only contains the F-bit. Its location in the F channel is shown in Table 26.
5.1.1.2 E1 FALC Mode
In E1 mode (Pin E1/T1 = 1) there are 32 channels numbered from 0 to 31. The channels
are directly mapped into the corresponding 32 frame slots.
5.1.2 Generic Interface Mode (GIM)
The Generic Interface Mode (GIM) makes the framer interface more universal, so that
other framer/line interface units or T1/E1 transceivers can be connected directly to the
IWE8. Depending on the E1/T1 pin, the interface can be adopted to line bit rates of
1.544 MHz (T1 rate) or 2.048 MHz (E1 rate). The mode is enabled by setting bit om =
01B in “opmo”, see Chapter 7.24. Make sure that no clocks are applied to the transmitter
when switching to GIM (FTCKOi has to be disconnected to ensure proper port function).
5.1.2.1 T1 Mode
9 channel 7 25 channel 19
10 channel 8 26 channel 20
11 channel 9 27 channel 21
12 28
13 channel 10 29 channel 22
14 channel 11 30 channel 23
15 channel 12 31 channel 24
Table 26 F-Channel Format in T1 Mode
MSB F channel LSB
bit 1 bit 2 bit 3 bit 4 bit 5 bit 6 bit 7 bit 8
F-bit
FRCLK[7:0] Framer Receive Clock
Receive clock input at 1.544 MHz
FRDAT[7:0] Framer Receive Data
depending on bit “frri” in “opmo”:
0 = FRDAT is sampled with the falling edge of FRCLK
Table 25 Time slot Mapping in T1 Translation Mode 0 (cont’d)
Frame slot T1 channel Frame slot T1 channel
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 96 2003-01-20
1 = FRDAT is sampled with the rising edge of FRCLK
FRMFB[7:0] Framer Receive Multiframe Begin
Depending on bits p_ces in pcfN:
0 = Structured CES: A pulse on this pin designates the
first frame of a new multiframe
1 = Unstructured CES: Unused, no constant level
allowed
Depending on bit “rfpp” in “opmo”:
0 = FRMFB is active low
1 = FRMFB is active high
FRMFB is always sampled with the falling edge of FRCLK.
FRFRS[7:0] Framer Receive Frame Synchronization Pulse
Permanently inactive
FRLOS[7:0] Framer Receive Loss of Signalling
FTCKO[7:0] Framer Transmit Clock
depending on bits ftckn in ftcs:
00 = depending on bit “rts_eval” in “opmo”:
0 = Transmit clock input with 1.544 MHz
1 = Clock of ICRC is used as transmit clock and is
also switched to FTCKO pins (FTCKO is output
pin)
01 = FRCLK
10 = Clock derived from RFCLK
11 = No clock
FTDAT[7:0] Framer Transmit Data
depending on bit “ftri” in “opmo”:
0 = FTDAT is clocked with the falling edge of FTCKO
1 = FTDAT is clocked with the rising edge of FTCKO
FTMFS[7:0] Framer Transmit Multiframe Synchronization
Depending on bit p_ces in pcfN:
0 = Structured CES: Depending on “p_tx_mfs” in
“pcfN”:
0 = Superframe frame mode: FTMFS is asserted
every 12 frames (1.5 ms)
1 = Extended superframe mode: FTMFS is
asserted every 24 frames (3 ms)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 97 2003-01-20
Figure 24 Framer Interface in GIM T1
1 = Unstructured CES: Inactive level
Depending on bit “tfpp” in “opmo”:
0 = FTMFS is active low
1 = FTMFS is active high
FTFRS[7:0] Framer Transmit Frame Synchronization Pulse
FTFRS is asserted synchronously to the transmission of the F-bit
of each frame.
RFCLK Reference Clock
Reference clock for the internal clock recovery circuit
Depending on p_rx_em in pcfN: Optional emergency clock if
no transition on FRCLK is detected within 23 CLOCK cycles.
The segmentation continues using the RFCLK divided by four,
and using the byte-pattern programmed to a_emg_bpslct in
acfg for the cell payload.
FRCLKn
FRDATn
FRMFBn
FTFRSn
Framer Receive Interface:
Framer Transmit Interface:
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8 F
timeslot 23 timeslot 0 timeslot 1
FTCKOn
FTDATn
FTMFSn
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8 F
timeslot 23 timeslot 0 timeslot 1
12345678910111213141516
186 187 188 189 190 191 192 0185 12345678910111213141516184
186 187 188 189 190 191 192 0185184
Figimt1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 98 2003-01-20
5.1.2.2 E1 Mode
FRCLK[7:0] Framer Receive Clock
Receive clock input with 2.048 MHz
FRDAT[7:0] Framer Receive Data
depending on bit “frri” in “opmo”
0 = FRDAT is sampled with the falling edge of FRCLK
1 = FRDAT is sampled with the rising edge of FRCLK
FRMFB[7:0] Framer Receive Multiframe Begin
Depending on bits p_ces in pcfN:
0 = Structured CES: A pulse on this pin designates the
first frame of a new multiframe
1 = Unstructured CES: Unused, no constant level
allowed
depending on bit “rfpp” in “opmo”:
0 = FRMFB is active low
1 = FRMFB is active high
FRMFB is always sampled with the falling edge of FRCLK.
FRFRS[7:0] Framer Receive Frame Synchronization Pulse
Permanently inactive
FRLOS[7:0] Framer Receive Loss of Signalling
FTCKO[7:0] Framer Transmit Clock
depending on bits ftckn in ftcs:
00 = depending on bit “rts_eval” in “opmo”:
0 = Transmit clock input with 2.048 MHz
1 = Clock of ICRC is used as transmit clock and is
also switched to FTCKO pins (FTCKO is output
pin)
01 = FRCLK
10 = Clock derived from RFCLK
11 = No clock
FTDAT[7:0] Framer Transmit Data
depending on bit “ftri” in “opmo”:
0 = FTDAT is clocked with the falling edge of FTCKO
1 = FTDAT is clocked with the rising edge of FTCKO
FTMFS[7:0] Framer Transmit Multiframe Synchronization
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 99 2003-01-20
Figure 25 Framer Interface in GIM E1
Depending on bit p_ces in pcfN:
0 = Structured CES: Depending on “p_tx_mfs” in
“pcfN”:
0 = Double frame mode: FTMFS is asserted every
2 frames (250 µs)
1 = CRC multiframe mode: FTMFS is asserted
every 16 frames (2 ms))
1 = Unstructured CES: Inactive level
Depending on bit “tfpp” in “opmo”:
0 = FTMFS is active low
1 = FTMFS is active high
FTFRS[7:0] Framer Transmit Frame Synchronization Pulse
FTFRS is asserted synchronously to the transmission of the first
bit of the first timeslot of each frame.
RFCLK Reference Clock
Reference clock for the internal clock recovery circuit
Depending on p_rx_em in pcfN: Optional emergency clock if
no transition on FRCLK is detected within 23 CLOCK cycles.
The segmentation continues using the RFCLK divided by four,
and using the byte-pattern programmed to a_emg_bpslct in
acfg for the cell payload.
FRCLKn
FRDATn
FRMFBn
FTFRSn
Framer Receive Interface:
Framer Transmit Interface:
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
timeslot 31 timeslot 0 timeslot 1
FTCKOn
FTDATn
FTMFSn
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
timeslot 31 timeslot 0 timeslot 1
249 250 251 252 253 254 255 256248 12345678910111213141516
249 250 251 252 253 254 255 256248 12345678910111213141516
Figime1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 100 2003-01-20
5.1.3 Synchronous Modes (SYM)
In these modes, transmit and receive channels are synchronized. Therefore, they may
be used for synchronization of frame and multiframe based protocols, e.g. Frame based
SDT on E1-Lines.
Only one central clock, the external reference clock RFCLK, is used to clock the data on
the different ports. Two synchronous modes working at 2.048 MHz and 8.192 MHz for
E1lines are available. T1 is not supported.
For each of these modes a submode exists, providing global or port specific
synchronization.
If global synchronization of all transmit and receive channels is desired, bit “symn” in
“opmo” has to be deasserted. In this case FRMFB[0] is used for frame and multiframe
synchronization in receive and transmit direction of all ports.
Port specific frame and multiframe synchronization of transmit and receive channels is
enabled if bit “symn” in “opmo” is set. In this case frame and multiframe synchronization
in receive and transmit direction of each port is based on the corresponding FRMFB.
After reset all outputs and input/output ports of the framer interface are in tristate mode.
They will be enabled by setting bit “p_tx_act of the corresponding “Port Configuration
Register” (“pcfN”, see Chapter 7.1).
5.1.3.1 Synchronous Mode at 2.048 MHz (SYM2)
In SYM2 mode the framer interface is clocked with a 2.048 MHz clock connected to
RFCLK. The mode is enabled by setting bit om = 11B in “opmo”, see Chapter 7.24
All transmit and receive timeslots will be aligned to each other.
FRCLK[7:0] Framer Receive Clock
Unused
FRDAT[7:0] Framer Receive Data
depending on bit “frri” in “opmo”
0 = FRDAT is sampled with the falling edge of RFCLK
1 = FRDAT is sampled with the rising edge of RFCLK
FRMFB[7:0] Framer Receive Multiframe Begin
Depending on bits p_ces in pcfN:
0 = Structured CES: A pulse on this pin designates the
first frame of a new multiframe
1 = Unstructured CES: Unused, no constant level
allowed
depending on bit “rfpp” in “opmo”:
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 101 2003-01-20
Figure 26 Framer Interface in SYM2 E1
0 = FRMFB is active low
1 = FRMFB is active high
depending on bit “symn” in “opmo”:
0 = FRMFB[0] is used for frame and multiframe
synchronization in receive and transmit direction of
all ports. FRMFB[1:7] are unused
1 = FRMFB[N] is used for frame and multiframe
synchronization in receive and transmit direction of
corresponding ports
FRMFB is always sampled with the opposite clock-edge of
FRDAT.
FRFRS[7:0] Framer Receive Frame Synchronization Pulse
Unused
FRLOS[7:0] Framer Receive Loss of Signalling
FTCKO[7:0] Framer Transmit Clock
Unused
FTDAT[7:0] Framer Transmit Data
depending on bit “frri” in “opmo”:
0 = FTDAT is clocked with the rising edge of RFCLK
1 = FTDAT is clocked with the falling edge of RFCLK
FTMFS[7:0] Framer Transmit Multiframe Synchronization
Unused
FTFRS[7:0] Framer Transmit Frame Synchronization Pulse
Unused
RFCLK Reference Clock
Central framer interface clock with 2.048 MHz
RFCLK
FRDATn
FRMFB
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
FTDATn B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
timeslot 31 timeslot 0 timeslot 1
249 250 251 252 253 254 255 256248 12345678910111213141516
249 250 251 252 253 254 255 256248 12345678910111213141516
FRDATn sampled with rising edge of RFCLK
Fisym2e1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 102 2003-01-20
5.1.3.2 Synchronous Mode at 8.192 MHz (SYM8)
In SYM8 mode the framer interface is clocked with an 8.192 MHz clock connected to
RFCLK. The mode is enabled by setting bit om = 10B in “opmo”, see Chapter 7.24
All timeslots (transmit and receive) will be aligned to each other.
FRCLK[7:0] Framer Receive Clock
Unused
FRDAT[7:0] Framer Receive Data
FRDAT is sampled in the middle of the bit period on the falling
edge of RFCLK
FRMFB[7:0] Framer Receive Multiframe Begin
Depending on bits p_ces in pcfN:
0 = Structured CES: A pulse on this pin designates the
first frame of a new multiframe
1 = Unstructured CES: Unused
depending on bit “rfpp” in “opmo”:
0 = FRMFB is active low
1 = FRMFB is active high
depending on bit “symn” in “opmo”:
0 = FRMFB[0] is used for frame and multiframe
synchronization in receive and transmit direction of
all ports. FRMFB[1:7] are unused
1 = FRMFB[N] is used for frame and multiframe
synchronization in receive and transmit direction of
corresponding ports
FRMFB is always sampled with the opposite clock-edge of
FRDAT.
FRFRS[7:0] Framer Receive Frame Synchronization Pulse
Unused
FRLOS[7:0] Framer Receive Loss of Signalling
FTCKO[7:0] Framer Transmit Clock
Unused
FTDAT[7:0] Framer Transmit Data
FTDAT is clocked with the falling edge of RFCLK:
FTMFS[7:0] Framer Transmit Multiframe Synchronization
Unused
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 103 2003-01-20
Figure 27 Framer Interface in SYM8 E1
5.1.4 Echo Canceller Mode (EC)
In this mode (pin EC = 0) transmit and receive channels are synchronized.
The framer interface is clocked with an 8.192 MHz clock connected to RFCLK.
All receive channels and the channels transmitted on even ports (near-end signal with
echo) are synchronized by means of the FTFRS[0] pin. Shift exists between odd and
even FTDAT ports
FTFRS[7:0] Framer Transmit Frame Synchronization Pulse
Unused
RFCLK Reference Clock
Central framer interface clock with 8.192 MHz
FRCLK[7:0] Framer Receive Clock
Unused
FRDAT[7:0] Framer Receive Data
FRDAT is sampled in the middle of the bit period on the falling
edge of RFCLK
FRMFB[7:0] Framer Receive Multiframe Begin
Unused
FRFRS[7:0] Framer Receive Frame Synchronization Pulse
Unused
FRLOS[7:0] Framer Receive Loss of Signalling
FTCKO[7:0] Framer Transmit Clock
Unused
FTDAT[7:0] Framer Transmit Data
FTDAT is clocked with the falling edge of RFCLK:
RFCLK
FRDATn
FRMFB
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
FTDATn B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
timeslot 31 timeslot 0 timeslot 1
249 250 251 252 253 254 255 256248 12345678910111213141516
249 250 251 252 253 254 255 256248 12345678910111213141516
Fisym8e1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 104 2003-01-20
Figure 28 Framer Interface in EC Mode
FTMFS[7:0] Framer Transmit Multiframe Synchronization
Unused
FTFRS[7:0] Framer Transmit Frame Synchronization Pulse
FTFRS[0] is asserted synchronously to the transmission of the
first bit of the first timeslot of each frame. FTFRS[1:7] are unused
RFCLK Reference Clock
Central framer interface clock with 8.192 MHz
RFCLK
FRDATn
FTFRS0
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
FTDATn
even ports
B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8B8
timeslot 31 timeslot 0 timeslot 1
249 250 251 252 253 254 255 256248 1 2 3 4 5 6 7 8 9 10111213141516
249 250 251 252 253 254 255 256248 1 2 3 4 5 6 7 8 9 10111213141516
FTDATn
odd ports
B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8 B1 B2 B3 B4 B5 B6 B7 B8
251 252 253 254 255 256 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16
timeslot 31
timeslot 0 timeslot 1
B1 B2
249 250
FiECe1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 105 2003-01-20
5.2 UTOPIA Interface
Figure 29 UTOPIA Receive and Transmit Interfaces in Slave Mode
The UTOPIA receive and transmit interfaces are implemented according to the ATM
forum UTOPIA Level 2 Specification [6] and to the UTOPIA Level 1 Specification [5].
For UTOPIA level 2 compliant mode, the device is compatible to a PHY layer with 8 data
lines and 5 address lines.
In UTOPIA level 1 compliant mode the interface can be configured to ATM and PHY
layer with 8 data lines. In this case the address lines should be left unconnected.
According to the UTOPIA standard the ATM-Layer polls the PHY-Ports via the UTOPIA
address lines. If the address matches the programmed address range, the PHY controls
the flow of data via the TXCLAV or RXCLAV signal.
In transmit direction the PHY indicates via assertion of TXCLAV whether the
corresponding port is capable of accepting data. In case data can not be transferred to
the addressed port due to overrun of the programmed threshold of the port-specific cell
buffer, the TXCLAV won’t be activated.
In receive direction, RXCLAV is activated, if data is available at the addressed port.
Depending on the value of the “utmaster” bit in the “UTOPIA Configuration Register”
(“utconf”, see Chapter 7.34) the IWE8 will either act as an ATM -Layer (master mode)
or PHY-Layer (slave mode). As an ATM-Layer, the IWE8 can only work in UTOPIA level
1 compliant mode. As PHY Layer, IWE8 supports both, single PHY in UTOPIA level 1
compliant mode and single/multi PHY in UTOPIA level 2 compliant mode. The selection
between UTOPIA level 1 and level 2 can be done via the “utlevel” bit in “utconf”.
5.2.1 Port Addresses
The device can implement up to 8 PHY-Ports (= framer ports).
UTOPIA
Receive
Interface
(Level 2)
TXDAT[0-7]
TXADR[0-4]
TXCLK
TXPTY
TXSOC
TXCLAV
TXENB
RXDAT[0-7]
RXADR[0-4]
RXCLK
RXPTY
RXSOC
RXCLAV
RXENB
IWE8
UTOPIA
Transmit
Interface
(Level 2)
Urati
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 106 2003-01-20
In case it is configured for UTOPIA level 2 MPHY mode, the amount of implemented PHY
ports can be selected via the associated address range (“utconf[utrange]” with
utconf[mapping_mode] = 0).
In addition, the transmission of the UTOPIA port number via a user-defined field in the
ATM header enables multi PHY operation even in UTOPIA level 1 mode and UTOPIA
level 2 single PHY mode as described in Chapter 5.2.3.
In UTOPIA level 2 MPHY mode no port number mapping into the ATM header is done.
However, using this feature in UTOPIA level 2 mode, will give access to all PHY ports
while the UTOPIA interface block is running in single PHY mode. For UTOPIA level 2
compliant multi PHY operation, “mapping_mode” should be reset. In this case the UDF
field is set to all zero.
In UTOPIA level 2 MPHY mode the port number is transported via the address pins.
“utbaseadr” in “utconf” defines the base address under which the ports will be
accessible. In UTOPIA level 1 mode, “utbaseadr” has to be set to "0" otherwise cells are
discarded.
If the device is in single PHY mode, it will react on the address, written into “utbaseadr”.
In multi PHY mode, the device will be accessible inside a window from “utbaseadr” to
“utbaseadr” + “utrange”. Where the nth port can be accessed at “utbaseadr” + n.
5.2.2 Back Pressure/ATM Cell Discarding
Backpressure describes the mechanism that controls the TXCLAV signal in UTOPIA
PHY mode. IWE8 supports two kinds of backpressure mechanisms, a general and a port
specific one.
Cells that are destined to inactive ports or channels are generally discarded.
5.2.2.1 General Backpressure Mechanism
The general backpressure mechanism depends only on the filling level of the 4 cell
UTOPIA input buffer.
General backpressure is active in all UTOPIA configurations:
UTOPIA level 1compliant mode (utlevel=1)
UTOPIA level 2 PHY mode, where the selection between ports is done by ATM
header fields (mapping_mode!=0)
UTOPIA level 2 PHY mode, with port selection by ATM header fields disabled
(mapping_mode=0) and the port threshold mode (“p_thr_m” bits in “pcfN”) disabled.
The general threshold is defined in the “Threshold Register” (“thrshld”, see
Chapter 7.33).
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 107 2003-01-20
5.2.2.2 Port Specific Backpressure Mechanism
In addition to the general backpressure mechanism, port specific backpressure is
available for ATM ports, when using the IWE8 as a UTOPIA level 2 PHY device
(“utconf[utlevel]” =0, “utmaster” = 0, “mapping_mode” =0 and “pcfN[p_atm]” =1). It needs
to be explicitly enabled with the “p_thr_m” bits in the “Port Configuration Registers”
(“pcfN”, see Chapter 7.1).
Whenever the port transmit buffer filling level falls below the programmed value and the
port is selected via the UTOPIA PHY address, the TXCLAV signal is activated, allowing
another data transfer for that port. If this transfer exceeds the predefined buffer filling
level, the UTOPIA interface immediately enters backpressure state for this port.
When using the port specific backpressure mechanism (“p_thr_m” = 01B or 10B) the
general threshold defined in the “Threshold Register” (“thrshld”, see Chapter 7.33)
should be higher than the port specific threshold defined in the “Threshold Port Register”
(“thrspN”, see Chapter 7.38 to Chapter 7.41).
5.2.3 Sideband Signals of the UTOPIA Interface
In UTOPIA level 1 mode or UTOPIA level 2 single PHY mode, the framer port number
("port_nr[2:0]") can be transmitted via the UTOPIA interface. The field contains the
number of the physical (framer) port associated with that ATM cell. Its location inside the
ATM header is configurable via the “mapping_mode” bits in “utconf” (Chapter 7.34).
Possible locations are: GFC[3:1], VPI[7:5], VCI[15:13], VCI[7:5] or UDF[2:0].
In AAL mode, the channel number ("channel_nr", first timeslot number of a channel,
reference timeslot) has to be transmitted on the UTOPIA transmit interface via VCI[4:0].
If no discarding of cells with uncorrectable HEC error is selected on a specific port via
bits “a_hec_mode” in the register “acfg” (Chapter 7.2) and "p_cell_disc" in the register
"pcfN" (Chapter 7.1) an HEC error flag (HEF) indicates corrupted HEC by setting the
most significant bit in the user defined octet at the UTOPIA interface. For correct
operation bit "p_cell_disc" must be cleared.
The bit ENB, bit 5 of the user defined octet, is responsible for the decision if cell
discarding shall base on CLP or CLPI.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 108 2003-01-20
Figure 30 Utopia Sideband Signals
port_nr[2:0]
GFC[3:1] / VPI[11:9]
port_nr[2:0]
VPI[7:5]
VPI[3:0]
port_nr[2:0]
VCI 15..13
port_nr[2:0]
VCI[7:5]
channel_nr[3:0]
VCI[3:0] PTI
port_nr[2:0]
UDF[2:0]UDF[4:3]
LSBMSB
GFC[0]
/ VPI[8]
VPI[4]
VCI[12]
VCI[11:8]
channel_
nr[4]
VCI[4]
CLP
HEF
UDF[7]
CLPI
UDF[6]
ENB
UDF[5]
User Defined Field
Header octet 1
Header octet 2
Header octet 3
Header octet 4
UTOPIA sideband
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 109 2003-01-20
5.3 IMA Interface
The IWE8 has provisions to support the Inverse Multiplexing over ATM (IMA) protocol
implemented in an external component. These are:
An IMA interface
A programmable threshold between read and write pointer of the mapping buffer.
If an Uncorrectable HEC Error (UNCHEC) is detected, the cell is discarded and the
UNCHEC signal will be asserted. At the same time the port number, where the cell came
from, will be available at pins PN[2:0].
The ATM Transmit Buffer Threshold Crossing (ATBTC) signal becomes active when the
difference between write and read pointer of the ATM Transmit Buffer becomes smaller
than the threshold selected with bits “bufthr” in the “Operation Mode Register” (“opmo”,
see Chapter 7.24). At the same time the Port Number, where the cell came from, will be
available at pins PN[2:0].
At the IMA interface the IWE8 operates in cycles of 12 system clocks. ATBTC can
become active during cycle #3, the UNCHEC can become active during cycle #9. The
Port number is always active for 6 cycles.
Figure 31 IMA Interface Protocol
For more detailed information on the IMA interface refer to the Application Hint “Inverse
Multiplexing for ATM (IMA) with the Interworking Element IWE8”.
PN0..2
UNCHEC
ATBTC
CLOCK
01234567891011
Imai
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 110 2003-01-20
5.4 Clock Recovery Interface
It is possible to use an external device for clock recovery instead of the ICRC. Therefore
an external clock recovery interface is provided.
It allows the transmission and reception of serial communication frames containing
SRTS values or ACM buffer filling levels to and from an external clock recovery circuit.
The usage is controlled by the bits “rtsgen” and “rts_eval” in the Operation Mode
Register (“opmo”, see Chapter 7.24).
The Clock Recovery Interface is a 5 line serial interface: 1 data input SDI, 2 data outputs
SDOD and SDOR and 1 synchronization output SSP. The interface allows connection to
external clock recovery circuits. Two methods for clock recovery are supported:
Synchronous Residual Time Stamp (SRTS) and Adaptive Clock Method (ACM). The
IWE8 also allows a combination of SRTS and ACM.
The data sent over the serial lines is always formatted in frames of 32 bits.
The SSP pulse indicates the frame start for both directions. The inter-frame delay should
be equivalent to the payload of 8 ATM cells (e.g. for completely filled cells without SDT
every 3008 clock periods). Each valid frame is supposed to contain a valid RTS value
Table 27 shows the interface frame format. Bit [31] is sent first. When no data is to be
sent, idle frames are transmitted consisting of bits [31:1] all 1 and parity bit[ 0] = 0.
Table 27 also indicates which data fields are used on the different interface signals.
Table 27 Clock Recovery Interface frame format
Bits Data field SDI SDOD SDOR
31- 29 111 Yes Yes Yes
28 - 25 RTS[3:0] Yes Yes No
24 - 11 buffer_fill[13:0] No Yes No
10 RTS_valid No Yes No
9 - 8 00 Yes Yes Yes
7 - 5 port_nr[2:0] Yes Yes Yes
4 - 2 type[2:0]
001: RTS only
010: “buffer_fill” only
011: RTS + “buffer_fill”
111: reset RTS logic
others: not used
No
No
No
No
Yes
Yes
Yes
No
No
No
No
Yes
1 frame_invalid Yes Yes Yes
0 odd_parity Yes Yes Yes
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 111 2003-01-20
To allow the external SRTS generation logic to synchronize with the cell segmentation
process, the IWE8 will output a frame with type = 111 on the SDOR signal when the
segmentation of the first ATM cell for a selected channel starts. The first two sequences
of 8 ATM cells will contain a dummy RTS value which is programmable in the “ASIC
Configuration Register” (“acfg”, see Chapter 7.2). From the third sequence on the
values received on the SDI input will be used.
The IWE8 has internal ‘RTS Buffers’ for 2 RTS values per port. When one of the ‘RTS
Buffers’ overflows, the value in excess will be omitted and a bit in the Extended Interrupt
Status Register 2 (eis2, see Chapter 7.20) will be set. When ‘RTS Buffer’ underflow
occurs, the last received RTS value will be repeated in the next sequence of 8 ATM cells.
The RTS value extracted from a cycle of 8 ATM cells with sequence count 0 to 7, is
transmitted on SDOD when the cell with sequence count 1 from the next cycle is
received. The ‘RTS_valid’ field is used to indicate whether the extracted RTS value is
correct or not. An extracted RTS is accepted as valid if in the previous cycle of 8 cells
the cells with SN = 1, 3, 5 and 7 were present and were accepted as valid cells.
The buffer filling level is transmitted for use with the Adaptive Clock Method (ACM) and
is expressed as a number of octets contained in the ‘Reassembly Buffer’. The buffer
filling level is transmitted every time when a new ATM cell for the selected channel is
received.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 112 2003-01-20
5.5 Microprocessor Interface
IWE8 contains internal registers, 4 internal RAMs and an external RAM that can be read
and written via the Microprocessor Interface.
As access to the internal registers is 16-bit oriented, the Microprocessor Address Bus
(MPADR) is designed for 16-bit boundaries. Access to the 32-bit-wide internal or
external RAM has to be executed in two consecutive 16 bit cycles.
The Microprocessor data bus (MPDAT) has “little endian” word order. Little to big endian
conversion may be implemented either by initialization of the microcontroller or by
hardwiring MPDAT[7:0] to DATA[15:8] and MPDAT[15:8] to DATA[7:0] respectively,
The 32 bit oriented accesses have to be done by two consecutive 16 bit accesses, the
first with MPADR[0] = 0 and the second with MPADR[0] = 1. The IWE8 will not verify
whether the address bits MPADR[17:1] during the second access are the same as
during the first access.
The data of the first of two consecutive write cycles (MPADR[0] = 0) is written temporarily
into an internal write-cache register. The second write cycle (MPADR[0] = 1) causes the
data to be written into internal or external RAM. Bits [15:0] are written from the internal
write-cache register and bits [31:16] are transferred from MPDAT
During the first of two consecutive read cycles (MPADR[0] = 0), the 32 bit data are
actually read from internal or external RAM. Bits [15:0] are transferred to the databus
MPDAT. Bits [31:16] are written into an internal read-cache register. During the second
read (MPADR[0] = 1) the read-cache register is transferred to the databus. When only
bits [15:0] are needed, the second read cycle can be omitted.
For proper operation without acknowledge handshake via MPRDY 23 waitstates can be
used.
5.5.1 Interrupt Handling
The IWE8 provides two independent interrupt pins MPIR1 and MPIR2. The interrupt
handling software should read the interrupt status registers to identify the causes of the
interrupt.
MPIR1 is the main interrupt pin indicating a special event in the IWE8. The interrupt
cause can be determined by reading Interrupt Status Register 1 ("isr1", see
Chapter 7.18). Each of the interrupt sources can be individually masked in the
corresponding interrupt mask register. If the interrupt source is masked, the interrupt pin
MPIR1 will not be asserted when the corresponding event occurs.
MPIR2 is an auxiliary interrupt pin. The IWE8 provides two sets of 8 independent timers
in external RAM (timer set 1 and 2). Timer set 2 can be used independently from the rest
of the IWE8 driver software. When one of the timers of timer set 2 expires, a bit will be
set in the Interrupt Status Register 2 ("isr2", see Chapter 7.23) and MPIR2 will be
asserted.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 113 2003-01-20
5.5.2 Microprocessor Interface Mode
The IWE8 microprocessor interface allows connection of Intel type microprocessors as
well as Motorola type microprocessors (e.g. the PowerPC).
The Microprocessor Interface Mode is determined via the status of the pins PMT and
TBUS at the positive edge of the internal reset. Therefore, PMT and TBUS levels have
to be kept at least 3 clock cycles after deassertion of RESET.
The mode currently assigned to the microprocessor interface is visible via “mtypsel” in
the “Version Register” (“vers”, see Chapter 7.16).
Intel Mode
The connection of the 16 bit Intel compatible asynchronous microprocessor interface to
an Intel 386EX processor is shown in Figure 32.
If the ready signal at pin MPRDY shall be used, a glue logic between MPRDY of the
IWE8 and RDY of the 386EX is required, which generates an active low signal with 1
microprocessor cycle length after a rising edge detection of the MPRDY signal.
Figure 32 Connection of IWE8 to an Intel Type Microprocessor
Motorola Mode
Figure 33 shows the connection of the 16 bit Motorola compatible asynchronous
interface to the MC68xxx.
Table 28 Configuration of the Microprocessor Interface Mode
PMT TBUS Mode
0 0 Intel Mode
1 1 Motorola Mode
INTi
INTj
DATA[0-15]
CSn
RD
WR
ADR[1-18] MPADR[0-17]
MPDAT[0-15]
MPIR2
MPIR1
MPRD
MPCS
MPWR
IWE8
Intel i386 EX
Coitm
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 114 2003-01-20
Figure 33 Connection of IWE8 to an Motorola Type Microprocessor
INTi
INTj
DATA[0-15]
CSn
R/W
DS
A[1-18] MPADR[0-17]
MPDAT[0-15]
MPIR2
MPIR1
MPTS
MPCS
MPRW
IWE8MC 68xxx
MPTA
DSACK1
comom
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 115 2003-01-20
5.6 External RAM Interface
The IWE8 needs to be connected to an external synchronous SRAM of 64k x 33 bits with
parity protection or 64k x 32 bits without parity protection.
For proper operation FT (Flow Through) SSRAM is needed. Pipelined SSRAM can not
be used, as this type has additional registered outputs.
A possible connection with 1 SRAM 64k x 36 component is shown in Figure 34.
.
Figure 34 External RAM Connection
The IWE8 has a fixed RAM interface cycle of 12 clock periods. A sequence of
6 consecutive read cycles (addresses AR1 to AR6), a dummy address cycle and
5 consecutive write cycles (addresses AW1 to AW5) is continuously repeated. The
timing of RMADC and RMOE is always fixed as shown in Figure 35. Whether the IWE8
reads data from the external RAM or writes data into the external RAM is controlled by
the RMCS and RMWR signals. In Figure 35, data R1 and R3 are actually read by the
IWE8, and data W1 and W3 are actually written into the external RAM.
IWE8
RMDAT[0-32]
RMWR
RMCS
RMADC
RMOE
RMADR[0-15]
RMCLK
SRAM 64K x 36
D[0-35]
OE
WR
ADSC
CLK
A[0-15]
CS
erc
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 116 2003-01-20
Figure 35 RAM Interface Protocol
R1 R2 R3 R4 R5 W1 W2 W3 W4 W5 R1W5
R1 R2 R3 R4 R6W5 W1 W2 W3 W4 W5
RAM cycle
RMADC
RMCLK
RMADR
RMOE
RMDAT
RMWR
RMCS
R6
R5
Ram Interface Protoc
o
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 117 2003-01-20
5.7 Boundary Scan Interface
The boundary scan interface implements the Test Access Port (TAP) as defined in IEEE
Standard 1149.1-1990 [19] including the optional TRST reset signal.
The device identification register, the instruction register and boundary-scan register are
described in the electrical characteristics.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Interface Description
Data Sheet 118 2003-01-20
5.8 Master Clock
The basic processing time of an octet in the IWE8 is 12 clock cycles. As the time needed
to process one octet for each of the 8 ports must be less than the time required to transfer
one octet over a framer interface, this leads to the condition:
[15]
with:
m = 12 master-clock cycles needed for one octet per port
o = 8 ports
f = Framer-clock cycles per bit
b = 8 bits per octet
[16]
Table 29 Master Clock Frequency Depending on Mode
Mode TCLOCK F
CLOCK
FAM, SYM8 and EC < 1/3 x TFramerCLK > 3 x FFramerCLK = 3 x 8.192 MHz
GIM E1 and SYM2 < 1/12 x TFramerCLK > 12 x FFramerCLK = 12 x 2.048 MHz
GIM T1 < 1/12 x TFramerCLK > 12 x FFramerCLK = 12 x 1.544 MHz
mo×T×CLOCK fb×TFramerClk
×<
TClock
f
12
------T
FramerClk
×>
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 119 2003-01-20
6 Memory Structure
The IWE8 occupies an address space of 256k x 16 bits. The lower 128k x 16 bits are
used for internal registers and internal configuration RAM’s. The upper 128k x 16 bits are
used to address external RAM.
Figure 36 Memory Model
The 4 internal configuration RAMs are organized as 256 x 32 bit memories, but RAM4
has only 16 bits implemented (bit positions 16 to 31 are always read as "0").
MPADR[17:0] RMADR[15:0]
3FFFFH128k ×16 64k ×32 FFFFH
External RAM
20000H0000H
1FFFFH
Not used
00A00H
009FFH512 ×16 256 ×32
Internal RAM4
00800H
007FFH512 ×16 256 ×32
Internal RAM3
00600H
005FFH512 ×16 256 ×32
Internal RAM2
00400H
003FFH512 ×16 256 ×32
Internal RAM1
00200H
001FFH512 ×16
Internal Registers
00000H
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 120 2003-01-20
The external RAM is organized as a 64k x 32 bit parity protected memory.
Accesses to internal configuration RAM’s or external RAM are always 32 bit oriented.
6.1 Internal Configuration RAM’s
The 4 internal 256 x 32 bit configuration RAM’s (RAM1, RAM2, RAM3 and RAM4) are
used to assign the timeslots of the Framer Receive and Framer Transmit interfaces to
ATM channels. For each port there are 32 entries. RAM1 is used to define the timeslots
of the Framer Receive ports, and RAM2 and RAM3 are used to define the Framer
Transmit ports. RAM4 is responsible for CAS conditioning and freezing in transmit
direction
When the contents of the internal RAMs have been altered by the software, the internal
state machines will load the new values within the next 1.5 frame cycles (187.5 µs). Up
to that point of time the previous values are used.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 121 2003-01-20
6.1.1 RAM1: Receive Port Configuration
Read/write Address 00200H to 003FFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size 256K ×32 bits: 8 ports x 32 slots x 1 doubleword
6.1.1.1 RAM1: ATM Receive Reference Slot
Read/write Address 00200H to 003FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
MPADR 17161514131211109876543210
000000001 port_nr
[2:0]
slot[4:0]
31 24
Not used
23 16
Not used
15 8
Not used
7 0
ocd_start
_intrpt
ocd_end
_intrpt
go_hunt delete_
idle_cells
x43_
descram
bling
channel_mode[1:0] ref_slot
= 1
ocd_start_
intrpt
Generate interrupt when OCD state starts
0 = Disabled
1 = Enabled
ocd_end_
intrpt
Generate interrupt when OCD state ends
0 = Disabled
1 = Enabled
go_hunt Go to hunt state
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 122 2003-01-20
Note: To allow IWE8 internal initialization, all channels must remain in inactive mode for
at least 250 µs after activation of the port (i.e. setting pcfN[p_rx_act] = 1). During
this time the device connected to the Framer Receive Interface has to be in normal
operation.
6.1.1.2 RAM1: ATM Receive Continuation Slot
Read/write Address 00200H to 003FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
0 = Cell delineation finite state machine normal operation
1 = Cell delineation finite state machine forced in hunt state
Only the transition 0 1 forces the hunt state. Counter (number
of times SYNC state is left) is not incremented. Ocd_start
interrupt is not generated.
delete_idle_
cells
Delete idle/unassigned cells enable
0 = Disabled
1 = Enabled
x43_de
scrambling
ATM cell payload descrambling enable
0 = Disabled
1 = Enabled
channel_
mode
Channel mode
00 = Inactive mode
01 = Active mode (normal mode)
10 = Standby mode
11 = Active mode (normal mode)
ref_slot Reference slot indicator
1 = This slot is a reference slot
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 123 2003-01-20
6.1.1.3 RAM1: AAL Receive Reference Slot
Read/write Address 00200H to 003FFH
Reset value: Not applicable. RAM must be reset and initialized via SW
.
31 24
Not used
23 16
Not used
15 8
Not used
7 0
Not used ref_slot_nr[4:0] cont_slot
=1
ref_slot
=0
ref_slot_nr Reference slot number
Number of the reference slot of this channel
cont_slot Continuation slot indicator
1 = This slot is a continuation slot
ref_slot Reference slot indicator
0 = This slot is not a reference slot
31 24
next_slot_nr[4:0] sdt_mfs sig_cond srts
23 16
subst_bpslct[1:0] dcor dcor_random_nr[4:0]
15 8
aal0 part_fill[5:0] band_
width[4]
7 0
band_width[3:0] sdt channel_mode[1:0] ref_slot
=1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 124 2003-01-20
next_slot_nr Next slot number
If band_width > 0 next_slot_nr points to the next slot of this channel.
If band_width = 0 and CAS is activated next_slot_nr[3:0] will be used as
signalling conditioning nibbles.
If band_width = 0 and CAS is not activated next_slot_nr is don’t care.
sdt_mfs SDT multiframe pulse select
X = If [aal0] = 1 or [sdt] = 0 or pcfN[p_ces] = 1
0 = Start of structure is frame pulse
1 = Start of structure is multiframe pulse as defined by
pcfN[p_tx_mfs]
sig_cond Signalling conditioning upstream
0 = CAS freezing upstream enabled in "loss of signal" condition
1 = CAS conditioning upstream enabled in "loss of signal" condition
srts SRTS enable
Enables RTS value insertion into AAL1 SAR-PDUs
X = If pcfN[p_srts] = 0 or [aal0] = 1
0 = Disabled
1 = Enabled
subst_
bpslct
Substitute byte-pattern select
00 = Select byte-pattern 0, defined in bp10[bp0]
01 = Select byte-pattern 1, defined in bp10[bp1]
10 = Select byte-pattern 2, defined in bp32[bp2]
11 = Select byte-pattern 3, defined in bp32[bp3]
dcor Decorrelation circuit enable
0 = Disabled
1 = Enabled
dcor_
random_nr
Decorrelation random Number
X = if [dcor] = 0
aal0 AAL0 enable
0 = Disabled (AAL1 is used)
1 = Enabled (instead of AAL1)
part_fill Partially filled cell filling level
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 125 2003-01-20
Note: To allow IWE8 internal initialization, all channels must remain in inactive mode for
at least 250 µs after activation of the port (i.e. setting pcfN[p_rx_act] = 1). During
this time the device connected to the Framer Receive Interface has to be in normal
operation.
Note: If frame based SDT without CAS is used and filling level 45, the condition
band_width part_fill has to be fulfilled for correct operation.
Multiframe based SDT without CAS should not be used.
4 to
48
AAL0:
[aal0] = 1
4 to
47
AAL1 unstructured CES:
[aal0] = 0, pcfN[p_ces] = 1
4 to
47
AAL1 structured CES without CAS1):
[aal0] = 0, pcfN[p_ces] = 0, pcfN[p_cas] = 0
4+Cb
to 46
AAL1 structured CES with CAS2):
[aal0] = 0, pcfN[p_ces] = 0, pcfN[p_cas] = 1
band_width band_width
N-1 Structured CES (with N = number of timeslots of the channel)
1FHUnstructured CES (pcfN[p_ces] = 1)
sdt SDT enable
X = If pcfN[p_ces] = 1 or [aal0] = 1
0 = Disabled
1 = Enabled
channel_
mode
Channel mode
00 = Inactive mode
01 = Active mode (normal mode)
10 = Standby mode
11 = Substitute mode
ref_slot Reference slot indicator
1 = This slot is a reference slot
1) non-P format, cell may have only 46 user data octets in P format
2) Cb: Required bytes for the CAS sub-block in an ATM cell
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 126 2003-01-20
6.1.1.4 RAM1: AAL Receive Continuation Slot
Read/write Address 00200H to 003FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
31 24
next_slot_nr[4:0] Not used
23 16
Not used sig_cond_nibble[3:0] fourth_
slot_nr[4]
15 8
fourth_slot_nr[3:0] third_slot_nr[4:1]
7 0
third_slot
_nr[0]
ref_slot_nr[4:0] cont_slot
= 1
ref_slot
=0
next_slot_nr Next slot number
Number of the next slot of this channel. When no continuation slots exist,
the entry “next_slot_nr” should refer to the reference slot.
sig_cond_
nibble
4 bits for signalling conditioning
It is possible to have different signalling conditioning nibbles for all slots
of a channel except for the first two slots of a channel. The first slot in a
channel will always use the same nibbles as the first continuation slot.
fourth_slot_
nr
Fourth slot number
Number of the fourth slot of this channel
X = If [band_width] < 3
third_slot_
nr
Third slot number
Number of the third slot of this channel
X = If [band_width] < 2
ref_slot_nr Reference slot number
Number of the reference slot of this channel
cont_slot Continuation slot indicator
1 = This slot is a continuation slot
ref_slot Reference slot indicator
0 = This slot is not a reference slot
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 127 2003-01-20
6.1.1.5 RAM1: ATM or AAL Receive Idle Slot
Read/write Address 00200H to 003FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
6.1.2 RAM2: Transmit Port Configuration
Read/write Address 00400H to 005FFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size 256K ×32 bits: 8 ports x 32 slots x 1 doubleword
6.1.2.1 RAM2: ATM Transmit Reference Slot
Read/write Address 00400H to 005FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
31 24
Not used
23 16
Not used
15 8
Not used
7 0
Not used cont_slot
= 0
ref_slot
=0
cont_slot Continuation slot indicator
0 = This slot is not a continuation slot
ref_slot Reference slot indicator
0 = This slot is not a reference slot
MPADR 17161514131211109876543210
000000010 port_nr
[2:0]
slot[4:0]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 128 2003-01-20
Note: RAM slot 1 has always to be configured always as reference slot.
Note: To allow IWE8 internal initialization, all channels must remain in inactive mode for
at least 250 µs after activation of the port (i.e. setting pcfN[p_tx_act] = 1). During
this time the device connected to the Framer Transmit Interface has to be in
normal operation.
6.1.2.2 RAM2: ATM Transmit Continuation Slot
Read/write Address 00400H to 005FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
31 24
Not used
23 16
Not used
15 8
Not used
7 0
Not used x43_
scram-bli
ng
channel_mode[1:0] ref_slot
=1
x43_scram
bling
ATM cell payload scrambling enable
0 = Disabled
1 = Enabled
channel_
mode
Channel mode
00 = Inactive mode
01 = Active mode (normal mode)
10 = Standby mode
11 = Active mode (normal mode)
ref_slot Reference slot indicator
1 = This slot is a reference slot
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 129 2003-01-20
6.1.2.3 RAM2: AAL Transmit Reference Slot
Read/write Address 00400H to 005FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
31 24
next_slot_nr[4:0] = 00000 Not used
23 16
Not used
15 8
Not used
7 0
Not used ref_slot_nr[4:0] cont_slot
=1
ref_slot
=0
next_slot_nr Next slot number
0 = This field must be all 0 for ATM continuation slots
ref_slot_nr Reference slot number
Number of the reference slot of this channel
cont_slot Continuation slot indicator
1 = This slot is a continuation slot
ref_slot Reference slot indicator
0 = This slot is not a reference slot
31 24
next_slot_nr[4:0] Not used snp_
check
sn_
check
23 16
sc_fast sdt_mfs sdt_oos_nr[1:0] sdt_par sdt_once crv_en mcp_
reinit
15 8
aal0 part_fill[5:0] band_
width[4]
7 0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 130 2003-01-20
band_width[3:0] sdt channel_mode[1:0] ref_slot
=1
next_slot_nr Next slot number
Number of the second slot of this channel. When no continuation slots
exist, the entry “next_slot_nr” should refer to the reference slot.
X = If pcfN[p_ces] = 1
snp_check SNP field check enable
X = If [aal0] = 1 or [sn_check] = 0
0 = Disabled
1 = Enabled
sn_check SN field check enable
X = If [aal0] = 1
0 = Disabled
1 = Enabled
sc_fast SC algorithm select
X = If [aal0] = 1 or [sn_check] = 0
0 = Standard SC algorithm
1 = Fast SC algorithm
sdt_mfs SDT multiframe pulse select
X = If [aal0] = 1 or [sdt] = 0 or pcfN[p_ces] = 1
0 = Start of structure is frame pulse
1 = Start of structure is multiframe pulse
sdt_oos_nr Number of SDT out of sync errors before re-initialization buffer
X = If [aal0] = 1 or [sdt] = 0
00 = Re-initialize after 1 out of sync error (recommended)
01 = Re-initialize after 2 out of sync error
10 = Re-initialize after 3 out of sync error
11 = Not allowed, IWE8 will not be able to re-initialize
sdt_par SDT pointer parity check enable
X = If [aal0] = 1 or [sdt] = 0
0 = Disabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 131 2003-01-20
1 = Enabled
sdt_once SDT pointer appears once in 8 cell cycle
X = If [aal0] = 1 or [sdt] = 0
0 = All cells with CSI bit = 1 and even SN are supposed to contain a
P format SAR-SDU.
1 = Only the first cell with CSI bit = 1 and even SN in a cycle of 8 cells
is supposed to contain a P format SAR-SDU. (recommended for
SDT)
crv_en Data to Clock Recovery interface enable (RTS values and/or ACM buffer
filling levels) This bit may only be set for one channel per port.
X = if (pcfN[p_srts] = 0 and pcfN[p_acm] = 0) or acfg[a_crv_en] = 0
0 = Disabled
1 = Enabled
Only one channel per port may have crv_en set to 1.
mcp_reinit Microprocessor forced reassembly buffer reinitialization
The SW should set and reset this bit to continue proper operation.
0 = Disabled
1 = Enabled
aal0 AAL0 enable
0 = Disabled (AAL1 is used)
1 = Enabled (instead of AAL1)
part_fill Partially filled cell filling level
4 to
48
AAL0:
[aal0] = 1
4 to
47
AAL1 unstructured CES:
[aal0] = 0, pcfN[p_ces] = 1
4 to
47
AAL1 structured CES without CAS1):
[aal0] = 0, pcfN[p_ces] = 0, pcfN[p_cas] = 0
4+Cb
to 47
AAL1 structured CES with CAS2):
[aal0] = 0, pcfN[p_ces] = 0, pcfN[p_cas] = 1
band_width band_width
N (with N = number of timeslots for this channel)
X = if pcfN[p_ces] = 1
sdt Structured Data Transfer enable
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 132 2003-01-20
Note: To allow IWE8 internal initialization, all channels must remain in inactive mode for
at least 250 µs after activation of the port (i.e. setting pcfN[p_rx_act] = 1). During
this time the device connected to the Framer Transmit Interface has to be in
normal operation.
Note: If frame based SDT without CAS is used and filling level 45, the condition
band_width part_fill has to be fulfilled for correct operation.
Multiframe based SDT without CAS should not be used.
6.1.2.4 RAM2: AAL Transmit Continuation Slot
Read/write Address 00400H to 005FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
X = If pcfN[p_ces] = 1 or [aal0] = 1
0 = Disabled
1 = Enabled
channel_
mode
Channel mode
00 = Inactive mode
01 = Active mode (normal mode)
10 = Standby mode
11 = Active mode (normal mode)
ref_slot Reference slot indicator
1 = This slot is a reference slot
1) non-P format, cell may have only 46 user data octets in P format
2) Cb: Required bytes for the CAS sub-block in an ATM cell
31 24
next_slot_nr[4:0] Not used
23 16
Not used
15 8
Not used slot_index[4:0]
7 0
Not used ref_slot_nr[4:0] cont_slot
=1
ref_slot
=0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 133 2003-01-20
6.1.2.5 RAM2: ATM or AAL Transmit Idle Slot
Read/write Address 00400H to 005FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
next_slot_nr Next slot number
Number of the next slot of this channel. When no continuation slots exist,
the entry “next_slot_nr” should refer to the reference slot.
slot_index Index number of the current slot
X = if pcfN[p_cas] = 0
2 =
3 =
...
30 =
1st continuation slot
2nd continuation slot
...
29th continuation slot
ref_slot_nr Reference slot number
Number of the reference slot of this channel
cont_slot Continuation slot indicator
1 = This is a continuation slot
ref_slot Reference slot indicator
0 = This slot is not a reference slot
31 24
Not used
23 16
Not used
15 8
Not used idle_
bpslct[1]
7 0
idle_
bpslct[0]
Not used cont_slot
=0
ref_slot
=0
idle_bpslct Idle slot byte-pattern select
00 = Select byte-pattern 0, defined in bp10[bp0]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 134 2003-01-20
6.1.3 RAM3: Transmit Port Configuration Extended
Read/write Address 00600H to 007FFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size 256K ×32 bits: 8 ports x 32 slots x 1 doubleword
RAM3 needs only to be programmed in the case of an “AAL Transmit Reference Slot’.
In all other cases the RAM3 entry is don’t care.
6.1.3.1 RAM3: AAL Transmit Reference Slot
Read/write Address 00600H to 007FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
01 = Select byte-pattern 1, defined in bp10[bp1]
10 = Select byte-pattern 2, defined in bp32[bp2]
11 = Select byte-pattern 3, defined in bp32[bp3]
cont_slot Continuation slot indicator
0 = This is not a continuation slot
ref_slot Reference slot indicator
0 = This slot is not a reference slot
MPADR 17161514131211109876543210
000000011 port_nr
[2:0]
slot[4:0]
31 24
Not used starv_bpslct[1:0] starv_ini[10:8]
23 16
starv_ini[7:0]
15 8
buff_lsize[13:6]
7 0
buff_lsize[5:0] auto_
reinit_of
auto_
reinit_uf
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 135 2003-01-20
6.1.4 RAM4: Transmit Port Configuration Extended
Read/write Address 00800H to 009FFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size 256K ×32 bits: 8 ports x 32 slots x 1 doubleword
RAM4 needs only to be programmed in the case of an “AAL Transmit Reference Slot”
and in case of CAS usage. In all other cases the RAM4 entry is don’t care.
starv_bpslct Starvation byte-pattern select
00 = Select byte-pattern 0, defined in bp10[bp0]
01 = Select byte-pattern 1, defined in bp10[bp1]
10 = Select byte-pattern 2, defined in bp32[bp2]
11 = Select byte-pattern 3, defined in bp32[bp3]
starv_ini Number of starvation octets sent at reassembly buffer initialization.
0..
2046
The actual number of starvation octets sent is starv_ini + 1
2047 An unlimited number of starvation octets will be sent
buff_lsize Logical size of reassembly buffer in octets
auto_reinit_
of
Automatic reassembly buffer reinitialization at overflow
X = If [aal0] =1
0 = µP controlled reassembly buffer initialization
1 = automatic reassembly buffer initialization
auto_reinit_
uf
Automatic reassembly buffer reinitialization at underflow
X = If [aal0] = 1
0 = µP controlled reassembly buffer initialization
1 = automatic reassembly buffer initialization
MPADR 17161514131211109876543210
000000100 port_nr
[2:0]
slot[4:0]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 136 2003-01-20
6.1.4.1 RAM4: AAL Transmit Conditioning Slot
Read/write Address 00800H to 009FFH
Reset value: Not applicable. RAM must be reset and initialized via SW.
Note: Bit positions 16 to 31 are not implemented and always read as "0":
31 24
00000000
23 16
00000000
15 8
Not used
7 0
Not used cond_en cond_down_nibble[3:0]
cond_down
_nibble
CAS conditioning nibbles in downstream for the slot
cond_en Conditioning enable
0 = CAS downstream freezing enabled in underrun or pointer
mismatch condition
1 = CAS downstream conditioning enabled in underrun or pointer
mismatch condition
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 137 2003-01-20
6.2 External RAM
The IWE8 requires an external 64K × 32 bit RAM. A 33th bit is added for parity.
Figure 37 Structure of the IWE8 external RAM
6.2.1 Statistics Counters
Read/write Address 20000H to 21FFFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 4K ×32 bits: 8 ports x 32 channels x 16 counters.
The statistics counters are incremented when the “channel_mode” is active or standby,
and when the corresponding enable bit in the “catm” or “caal” register is set.
MPADR[17:0] RMADR[15:0]
3FFFFH64k ×16 32k ×32 FFFFH
30000HReassembly / ATM Transmit Buffers 8000H
2FFFFH32k ×16 16k ×32 7FFFH
28000HSegmentation / ATM Receive Buffers 4000H
27FFFH8128 x 16 4064 x 32 3FFFH
26040HCell Extraction Buffer 3020H
2603FH32 ×16 16 ×32 301FH
26020HCell Insertion Buffer 3010H
2601FH32 ×16 16 ×32 300FH
26000HTimers 3000H
25FFFH8k ×16 4k ×32 2FFFH
24000HInterrupt queue 2000H
23FFFH8k ×16 4k ×32 1FFFH
22000HStatistics Counter thresholds 1000H
21FFFH8k ×16 4k ×32 0FFFH
20000HStatistics Counters 0000H
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
10000 port_nr
[2:0]
channel_nr[4:0] counter_nr[3:0] 0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 138 2003-01-20
Table 30 Statistics Counters for ATM Ports 1)
1) For ATM ports, the counters are located in channel_nr = 00000B
counter_nr Counter contents
0 2)
2) Counter_nr 0 is common to all ports and is located in port_nr = 111B channel_nr = 11111B
Number of discarded cells due to output queue, ATM Receive Buffer
overflow
1 Number of received cells with correctable HEC errors
2 Number of received cells with non-correctable HEC errors
3 Number of times cell delineation SYNC state is left, except when forced
by the processor
4 Number of discarded cells due to ATM transmit buffer overflow
5 Number of cells which have been discarded because of CLP or CLPI
6 Not used
7 Not used
8 Not used
9 Not used
10 Not used
11 Not used
12 Not used
13 Not used
14 Not used
15 Not used
Table 31 Statistics Counters for AAL Ports1)
Counter_nr Counter contents
0 2) Number of discarded cells due to Output Queue or Segmentation Buffer
overflow
1 Not used
2 Number of cells written to the Reassembly Buffer. It excludes cells that
were discarded for any reason and cells that are inserted instead of lost
cells (atmfReassembledCells)
3 Number of times incoming MFB pulse is not synchronous to SDT start of
structure upstream (AAL1)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 139 2003-01-20
4 Number of cells causing a Reassembly Buffer overflow (AAL0 & AAL1).
It includes accepted cells that are causing the filling level to exceed the
predefined threshold and discarded cells due to the attempt of writing to
the Reassembly Buffer when the threshold is already exceeded.
5 Number of end of Reassembly Buffer overflow (AAL0 & AAL1). The
value is incremented upon acceptance of the next cell after Reassembly
Buffer overflow.
6 The count of the number of AAL1 header errors detected including those
corrected. Header errors include correctable and uncorrectable CRC,
plus bad parity. (atmfCESHdrErrors)
7 Number of times that the sequence number of an incoming AAL1
SAR-PDU causes a transition of the SC algorithm from "sync" to "out of
sequence" and from "invalid" to "out of sync"
8 Number of downstream “misinserted cells” detected by the AAL1
sequence count algorithm (atmfCESMisinsertedCells)
9 Number of downstream cells discarded by the AAL1 sequence count
algorithm
10 Number of rejected AAL1 SDT pointers due to parity error or wrong
pointer value (93 < pointer <127)
11 Number of SC cycles with more than one AAL1 SDT pointer field if only
one pointer is expected (sdt_once = 1)
12 Number of start of reassembly buffer underflow (AAL0 & AAL1)
(atmfCESBufUnderflow)
13 3) Number of inserted starvation cells (AAL0 & AAL1) due to reassembly
buffer underflow
14 Number of times the Reassembly Buffer is re-initialized due to AAL1
start of structure is out of sync with port start of structure (see
Chapter 4.4.1.11)
This records the count of the number of events in which the AAL1
reassembler found that an SDT pointer is not where it is expected, and
the pointer must be reacquired. This count is only meaningful for
structured CES. (atmfCESPointerReframes)
15 Number of downstream “lost cells” detected by the AAL1 sequence
count algorithm (atmfCESLostCells)
1) For AAL ports with unstructured CES, the counters are located in channel_nr = 00000B
2) Counter_nr 0 is common for all ports and is located in port_nr = 111B channel_nr = 11111B
Table 31 Statistics Counters for AAL Ports1) (cont’d)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 140 2003-01-20
The format of the counter entries is as follows:
6.2.2 Statistics Counter thresholds
Read/write Address 22000H to 23FFFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 4K ×32 bits: 8 ports x 32 channels x 16 counter thresholds
3) If the “auto-re-initialization on underflow” feature is enabled (RAM3.AAL Transmit
Reference Slot.auto_reinit_uf = 1B), the re-initialization of the Reassembly Buffer will terminate an underflow
status as soon as start of underflow is detected. Thus, the underflow status for the device is no longer valid
although the underflow condition still exists. No starvation cells due to underflow will be inserted and counter
13 will not increment Therefore, it is recommended to disable “auto-re-initialization on underflow”
(RAM3.AAL Transmit Reference Slot.auto_reinit_uf = 0B) and perform the re-initialization of the reassembly
buffer by software.
31 24
int_gen count_value[30:24]
23 16
count_value[23:16]
15 8
count_value[15:8]
7 0
count_value[7:0]
int_gen interrupt queue entry generated
Indicates if an interrupt queue entry was generated for this counter. Only
one interrupt queue entry per counter can be generated.
0 = False
1 = True
count_value counter value
4000_0000H indicates the maximum value. The counter will not
increment beyond this value
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 141 2003-01-20
The format of the counter threshold entries is as follows:
6.2.3 Interrupt Queue
Read/write Address 24000H to 25FFFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 4K ×32 bits
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
10001 port_nr
[2:0]
channel_nr
[4:0]
counter_nr
[3:0]
0
31 24
thres_act thres_value[30:24]
23 16
thres_value[23:16]
15 8
thres_value[15:8]
7 0
thres_value[7:0]
thres_act threshold active
0 = Disabled
1 = Enabled
thres_value threshold value
Thresholds beyond 4000 0000H will never create an interrupt queue
entry as the counter stops at this value
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
10010 interrupt_queue_addr[11:0] 0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 142 2003-01-20
For reading the Interrupt Queue refer to Chapter 4.6.3.
Each interrupt queue entry identifies a particular statistics counter that has reached its
threshold value. The format of the interrupt queue entries is as follows:
6.2.4 Timers
Read/write Address 26000H to 2601FH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 16 ×32 bits: 2 timer sets x 8 timers
31 24
Not used
23 16
Not used
15 8
iq_ne not used port_nr
[2:0]
channel_
nr[4]
7 0
channel_nr[3:0] counter_nr[3:0]
iq_ne interrupt queue not empty
0 = interrupt queue is empty, no further entries
1 = interrupt queue is not empty, further entries can be read
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
1001100000000 timer_nr[3:0] 0
timer_nr[3] Timer number
Selects the timer set
0 = Timer set 2 indicated on MPIR2
1 = Timer set 1 indicated on MPIR1
timer_nr
[2:0]
Timer number
Number of the associated timer
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 143 2003-01-20
The format of the timer entries is as follows:
Note: Internal register bit oamc[tim_set1_en] = 0 will disable all timers in set 1.
Internal register bit time[tim_set2_en] = 0 will disable all timers in set 2.
6.2.5 Cell Insertion Buffer
Read/write: Address 26020H to 2603FH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 16 ×32 bits: 1 cell x 16 doublewords
31 24
Not used
23 16
Not used
15 8
timer_en timer_value[14:8]
7 0
timer_value[7:0]
timer_en Timer enable
The timer_en bit can be used by the SW to start/stop/pause the timer.
Upon reaching timer_value = 0 the timer_en will be reset to 0
0 = Disabled
1 = Enabled
timer_value Timer value
When timer_en is set to 1, the timer_value will be decremented every
12 x 512 x TCLOCK (245.8 µS if fCLOCK = 25 MHz). The timer_value will
stop at 7FFFH indicated by an interrupt status bit in isr1 for timer set 1 or
in isr2 for timer set 2.
MPADR[17:0] RMADR[15:0]
2603FH301FH
Not Used
2603CH301EH
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 144 2003-01-20
The ATM header to be used for cell insertion has to be programmed at
MPADR = 26020H.
The format of the ATM Header entry is as follows:
6.2.6 Cell Extraction Buffer
Read/write Address 26040H to 27FFFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 8127 ×32 bits: 254 cells x 16 doublewords
2603BH301DH
ATM Cell Payload
26024H3012H
26023H
Not Used
26022H3011H
26021H
ATM Header
26020H3010H
31 24
VCI[3:0] PTI[2:0] CLP
23 16
VCI[11:4]
15 8
VPI[3:0] VCI[15:12]
7 0
GFC[3:0] or VPI[11:8] VPI[7:4]
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
1 0 0 1 1 cell_nr[7:0] + 2 double_word
[3:0]
0
MPADR[17:0] RMADR[15:0]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 145 2003-01-20
For reading the extraction buffer, refer to Chapter 4.10.
The format of the ATM header entry is as follows:
6.2.7 Segmentation/ATM Receive Buffers
Read/write Address 28000H to 2FFFFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size: 16K ×32 bits: 8 ports x 32 channels x 4 cells x 16 doublewords
MPADR[17:0] RMADR[15:0]
27FFFHCell #254 3FFFH
·
26060HCell #2 3030H
2605FH302FH
Not Used
2605AH302DH
26059H302CH
ATM Cell #1 Payload
26042H3021H
26041H
ATM Cell #1 Header
26040H3020H
31 24
VCI[3:0] PTI[2:0] CLP
23 16
VCI[11:4]
15 8
VPI[3:0] VCI[15:12]
7 0
GFC[3:0] or VPI[11:8] VPI[7:4]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 146 2003-01-20
6.2.7.1 ATM Receive Buffer
The SW does not need to access the ATM Receive Buffers.
6.2.7.2 Segmentation Buffer
The ATM header to be used for each channel has to be programmed at the address
given by:
All other locations should never be accessed as the data changes continuously.
The format of the ATM header entry in the cell insertion buffer is as follows:
6.2.8 Reassembly/ATM Transmit Buffers
Read/write Address 30000H to 3FFFFH
Reset value: Not applicable. RAM must be reset and initialized via SW
Memory size 32K ×32 bits: 8 ports x 32 channels x 8 cells x 16 doublewords
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
1 0 1 port_nr
[2:0]
channel_nr
[4:0]
cell_nr
[1:0]
double_word
[3:0]
0
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
1 0 1 port_nr[2:0] ref_slot_nr[4:0] 00B0000B0
31 24
VCI[3:0] PTI[2:0] CLP
23 16
VCI[11:4]
15 8
VPI[3:0] VCI[15:12]
7 0
GFC[3:0] or VPI[11:8] VPI[7:4]
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Memory Structure
Data Sheet 147 2003-01-20
The SW does not need to access the Reassembly/ATM Transmit Buffers.
RMADR 1514131211109876543210
MPADR 17161514131211109876543210
11 port_nr
[2:0]
channel_nr
[4:0]
cell_nr
[2:0]
double_word
[3:0]
0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 148 2003-01-20
7 Register Description
The internal registers occupy the lowest addresses. Accesses to the internal registers
are 16 bit oriented.
Entry size = 16 bit
Note: N = 0 .. 7
Table 32 Internal Registers
MPADR Width Name Register
00000H+ N 15 pcfN Port Configuration Register of Port N
00008H16 acfg ASIC Configuration Register
00009H3 oamc OAM Control Register
0000AH6 catm OAM-Counter Enable Register for ATM Ports
0000BH16 caal OAM-Counter Enable Register for AAL Ports
0000CH16 bp32 Byte-pattern Register 3 and 2
0000DH16 bp10 Byte-pattern Register 1 and 0
0000EH16 atmc ATM Control Register
0000FH16 rxid RX Idle/unassigned Cell Control Register
00010H16 txid TX Idle/unassigned Cell Control Register
00011H9 lpbc Loopback Control Register
00012H8 cfil Cell Fill Register for Partially Filled Cells
00013H16 imr1 Interrupt Mask Register 1
00014H1 time Timer Enable Register
00015H16 cdfs Cell Delineation FSM Status Register
00016H9 vers Version Register
00017H8 ckmo Clock Monitor Register
00018H16 isr1 Interrupt Status Register 1
00019H2 eis1 Extended Interrupt Status Register 1
0001AH8 eis2 Extended Interrupt Status Register 2
0001BH8 eis3 Extended Interrupt Status Register 3
0001CH16 eis4 Extended Interrupt Status Register 4
0001DH8 isr2 Interrupt Status 2 Register
0001EH14 opmo Operation Mode Register
0001FH16 ftcs FT Clock Select Register
00020H16 cfvp1 Cell Filter VCI Pattern Register 1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 149 2003-01-20
00021H16 cfvm1 Cell Filter VCI Mask Register 1
00022H16 cfvp2 Cell Filter VCI Pattern Register 2
00023H16 cfvm2 Cell Filter VCI Mask Register 2
00024H12 cfpt Cell Filter Payload Type Register
00025H5 cmd Command Register
00026H8 cfrp Cell Filter Read Pointer
00027H16 thrshld Threshold Register
00028H14 utconf UTOPIA Configuration Register
00029H16 cas1 CAS 1 Register
0002AH16 cas2 CAS 2 Register
0002BH4 cas3 CAS 3 Register
0002CH16 thrshp01 Threshold Register Ports 0 and 1
0002DH16 thrshp23 Threshold Register Ports 2 and 3
0002EH16 thrshp45 Threshold Register Ports 4 and 5
0002FH16 thrshp67 Threshold Register Ports 6 and 7
00030H16 eis0 Extended Interrupt Status Register 0
00031H16 lcdtimer LCD Timer Register
00032H- 00100HUnused
00101H11 irs Interrupt Source Register
00102H11 irm Interrupt Mask Register
00103H9 icrcconf ICRC Configuration Register
00104H+ N x 32 13 condN Configuration Downstream Register of Port N
00105H+ N x 32 7 irsN Interrupt Source of Port N
00106H+ N x 32 7 irmN Interrupt Mask of Port N
00107H+ N x 32 5 tsinN Test input Register of Port N
00108H+ N x 32 1 conuN Configuration Upstream Register of Port N
0010CH+ N x 32 14 avbN Average Buffer Filling of Port N
0010DH+ N x 32 4 asfN ACM Shift Factor of Port N
0010EH+ N x 32 13 tiniN Time of Initial Free Run of Port N
0010FH+ N x 32 12 treshN Threshold Out Of Lock Detection of Port N
00110H6 per Parity Errors at Clock Recovery Interface
00111H8 scri Synchronization Errors at Clock Recovery
Interface
Table 32 Internal Registers (cont’d)
MPADR Width Name Register
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 150 2003-01-20
00112H8 crifo ICRC Clock Recovery Interface FIFO Overflow
00113H6 icrcv ICRC Version Register
00114H+ N x 32 8 sruN SRTS FIFO Underflow of Port N
00115H+ N x 32 8 sroN SRTS FIFO Overflow of Port N
00116H+ N x 32 8 srrN SRTS Generator Reset of Port N
00117H+ N x 32 8 sriN SRTS Invalid Value Processed of Port N
00118H+ N x 32 8 atlN ACM Data Too Late of Port N
00119H+ N x 32 3 oolN Out of Lock Register of Port N
0011AH+ N x 32 3 statN Status Register of ICRC of Port N
0011BH+ N x 32 5 tsoutN Test Output Register of Port N
Table 32 Internal Registers (cont’d)
MPADR Width Name Register
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 151 2003-01-20
7.1 Port Configuration Registers (pcfN)
Read/write Address 00000H + N
Reset value: 0000.
15 8
Not used p_cell_
disc
p_thr_m[1:0] p_cas p_atm p_ces p_acm
7 0
p_srts p_slp p_ulp p_dlp p_rx_act p_rx_em p_tx_act p_tx_mfs
p_cell_disc Port Cell Discard Enable
X = When p_atm = 0 or acfg.a_hec_mode = 0
0 = Port in IMA mode:
No cell discard upon detection of uncorrectable HEC error.
The MSB in the UDF field of the ATM cell header at UTOPIA
interface will indicate the results of the HEC check
1 = Port in standard mode:
Cell discard upon detection of uncorrectable HEC error
p_thr_m Port threshold mode
This bit is relevant in ATM mode (p_atm=1) only.
00 = Port specific backpressure to UTOPIA is disabled. Entering this
value causes a reset of the corresponding filling level counter.
Resetting this counter during operation may result in an
inappropriate backpressure.
01 = Port specific backpressure to UTOPIA is enabled
Crossing the value defined in thrspN will result in port specific
backpressure. Values can range from 0 to 255 cells.
10 = Port specific backpressure to UTOPIA is enabled
Crossing the value defined in thrspN will result in port specific
backpressure. The amount of bytes defining the threshold value
equals 53 * C + B. With C representing the 2 most significant bits
of thrspN and B representing the 6 least significant bits of thrspN.
Values can range from 0 to 222 bytes.
11 = Port specific backpressure to UTOPIA is disabled
p_cas Port CAS enable
0 = Disabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 152 2003-01-20
1 = Enabled
p_atm Port ATM mode
0 = AAL (CES) mode port
1 = ATM (PHY) mode port
p_ces Port circuit emulation service
X = When p_atm = 1 and for PXB 4219 version
0 = Structured (N × 64 kbit/s)
1 = Unstructured
p_acm Port ACM enable
X = When p_atm = 1
0 = Disabled
1 = Enabled
p_srts Port SRTS enable
For the PXB4220 this bit enables SRTS clock recovery. This is only
useful for AAL ports in unstructured CES.
For the PXB4221 this bit is tied to "0". Writing "1" has no effect.
X = When p_atm = 1
0 = Disabled
1 = Enabled
p_slp Port serial loopback enable
0 = Disabled
1 = Enabled
p_ulp Port upstream UTOPIA loopback (works even if UTOPIA interface is
disabled)
0 = Disabled
1 = Enabled
p_dlp Port downstream UTOPIA loopback
0 = Disabled
1 = Enabled
p_rx_act Port receive activate
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 153 2003-01-20
p_rx_em Port receive emergency mode
Enables the automatic switch over to emergency mode
0 = Disabled
1 = Enabled
p_tx_act Port transmit activate
0 = Disabled (Framer outputs tristated)
1 = Enabled
p_tx_mfs Port transmit multiframe signal at pin FTMFS
E1/T1 = 0:
0 = T1 Superframe mode (12 frames = 1.5 ms)
1 = T1 Extended superframe mode (24 frames = 3 ms)
E1/T1 = 1:
0 = E1 Double frame mode (2 frames = 250 µs)
1 = E1 CRC multiframe mode (16 frames = 2 ms)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 154 2003-01-20
7.2 ASIC Configuration Register (acfg)
Read/write Address 00008H
Reset value: 0000H
15 8
a_icrc_
dwn
a_hec_
algor
a_hec_
mode
a_sw_
reset a_ut_en a_ur_en a_crv_en a_dummy
_rts[3]
7 0
a_dummy_rts[2:0] a_emg_bpslct[1:0] a_ovf_
cnt_en
a_ptr_
prty
a_even_
pck
a_icrc_dwn ICRC power down
Once the SRTS block is switched off, it can only be enabled by hardware
reset of the whole device.
0 = Enabled
1 = Disabled
a_hec_algor HEC detection, correction
0 = HEC algorithm according to ITU-T
1 = HEC algorithm according to ATM Forum
a_hec_
mode
Handling in case of faulty HEC
0 = Standard mode:
Cell discard upon detection of uncorrectable HEC error
1 = as defined in pcfN.p_cell_disc
a_sw_reset Software reset
Reset registers 0000H to 0031H including this bit.
0 = Normal
1 = Reset
a_ut_en UTOPIA transmit enable
0 = Disabled
1 = Enabled
a_ur_en UTOPIA receive enable
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 155 2003-01-20
a_crv_en Clock recovery interface enable
0 = Disabled
1 = Enabled
a_dummy_
rts
Dummy RTS value
Dummy RTS value that will be transmitted in the first and second SRTS
period after start of segmentation.
a_emg_
bpslct
Emergency byte-pattern select
00 = Byte-pattern 0, defined in bp10[bp0] selected
01 = Byte-pattern 1, defined in bp10[bp1] selected
10 = Byte-pattern 2, defined in bp32[bp2] selected
11 = Byte-pattern 3, defined in bp32[bp3] selected
a_ovf_cnt_
en
Output queue overflow counter enable
0 = Disabled
1 = Enabled
a_ptr_prty SDT pointer even parity generation
0 = Disabled: Fixed value in bit 7 of pointer field: “0”.
1 = Enabled (recommended)
a_even_pck Even parity check for internal/external RAM and UTOPIA
0 = Odd parity check enabled (default operation)
The parity checkers expect the normal parity.
1 = Even parity check enabled
The parity checkers expect the inverse parity. This mode tests
the proper operation of the parity generators/checkers.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 156 2003-01-20
7.3 OAM Control Register (oamc)
Read/write Address 00009H
Reset value: 0000H
15 8
Not used
7 0
Not used tim_
set1_en
dest_
read
oam_
act
tim_set1_en Timer set 1 enable
0 = Disabled
1 = Enabled
dest_read Destructive read mode
0 = Disabled
1 = Enabled: OAM counter values in the external RAM are reset after
being read by the micro-processor.
(Only accepted if “oam_act” = 1)
oam_act OAM active
0 = The protocol monitoring is disabled and the microprocessor can
read and write the complete external RAM for test.
1 = The protocol monitoring is enabled and the RAM arbiter grants
both the protocol monitoring and the microprocessor access to
the external RAM. Reading any address of Interrupt Queue by
the microprocessor always yields the first interrupt in the queue.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 157 2003-01-20
7.4 OAM-Counter Enable Register for ATM Ports (catm)
Read/write Address 0000AH
Reset value: 0000H
15 8
Not used
75 0
Not used cnt_atm_en[5:0]
cnt_atm_en OAM-counter enable for ATM ports
X = When pcfN[p_atm] = 0
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 158 2003-01-20
7.5 OAM-Counter Enable Register for AAL Ports (caal)
Read/write Address 0000BH
Reset value: 0000H
15 8
cnt_aal_en[15:8]
7 0
cnt_aal_en[7:0]
cnt_aal_en OAM-counter enable for AAL ports
X = When pcfN[p_atm] = 1
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 159 2003-01-20
7.6 Byte-Pattern Register bp3 and bp2 (bp32)
Read/write Address 0000CH
Reset value: FFFFH
15 8
bp3[7:0]
7 0
bp2[7:0]
bp3 Byte-pattern 3
bp2 Byte-pattern 2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 160 2003-01-20
7.7 Byte-Pattern Register bp1 and bp0 (bp10)
Read/write Address 0000DH
Reset value: FFFFH
15 8
bp1[7:0]
7 0
bp0[7:0]
bp1 Byte-pattern 1
bp0 Byte-pattern 0
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 161 2003-01-20
7.8 ATM Control Register (atmc)
Read/write Address 0000EH
Reset value: 7655H
15 8
alpha[3:0] delta[3:0]
7 0
coset[7:0]
alpha Number of consecutive incorrect HEC (SYNC HUNT)
delta Number of consecutive correct HEC (PRESYNC SYNC)
coset Coset value x-ored with HEC
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 162 2003-01-20
7.9 RX Idle/Unassigned Cell Control Register (rxid)
Read/write Address 0000FH
Reset value: 0101H
Note: Other header bits must be zero
15 8
prg_rx_hd[7:4] prg_rx_hd[3:0]
7 0
msk_rx_hd[7:0]
prg_rx_hd Programmable RX idle/unassigned cell header octet 1[7:4]
00H according to I.361
prg_rx_hd Programmable RX idle/unassigned cell header octet 4[3:0]
01H according to I.361
msk_rx_hd Mask RX idle/unassigned cell header bits
Each bit masks the corresponding bit in prg_rx_hd
0 = Not masked:
1 = Masked
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 163 2003-01-20
7.10 TX Idle/Unassigned Cell Control Register (txid)
Read/write Address 00010H
Reset value: 016AH
Note: Other header bits are fixed to zero
15 8
prg_tx_hd[7:4] prg_tx_hd[3:0]
7 0
prg_tx_pl[7:0]
prg_tx_hd Programmable TX idle/unassigned cell header octet 1[7:4]
00H according to I.361
prg_tx_hd Programmable TX idle/unassigned cell header octet 4[3:0]
01H according to I.361
prg_tx_pl Programmable TX idle/unassigned cell payload octet
6AH according to I.432
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 164 2003-01-20
7.11 Loopback Control Register (lpbc)
Read/write Address 00011H
Reset value: 0000H
t
Note: Transparent loop: Data is looped and forwarded.
Non-transparent loop: Data is looped.
Note: For ATM ports with upstream UTOPIA loopback (pcfN[p_atm] = 1 and
pcfN[p_ulp] = 1), all cells are looped regardless of their VCI value. The vci_flt_ulp
and vci_val_ulp[4:0] bits are don’t care.
15 8
Not used tslp
7 0
tulp tdlp vci_flt_
ulp
vci_val_ulp[4:0]
tslp Transparent serial loop
0 = Non-transparent
1 = Transparent
tulp Transparent upstream UTOPIA loop
X = When pcfN[p_atm] = 1
0 = Non-transparent
1 = Transparent
tdlp Transparent downstream UTOPIA loop
0 = Non-transparent
1 = Transparent
vci_flt_ulp VCI filter enable for upstream UTOPIA loop
0 = Disabled (all VCIs are looped)
1 = Enabled (VCI selected by vci_val_ulp is looped)
vci_val_ulp 5 LSB of the VCI value (i.e. channel number) to be looped on upstream
UTOPIA loop
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 165 2003-01-20
7.12 Cell Fill Register for Partially Filled Cells (cfil)
Read/write Address 00012H
Reset value: 0000H
15 8
Not used
7 0
cfil[7:0]
cfil Dummy fill octet for partially filled cells
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 166 2003-01-20
7.13 Interrupt Mask Register 1 (imr1)
Read/write Address 00013H
Reset value: FFFFH
15 8
imr1[15:8]
7 0
imr1[7:0]
imr1 Each bit masks the corresponding bit in isr1
0 = Not masked
1 = Masked
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 167 2003-01-20
7.14 Timer Enable Register (time)
Read/write Address 00014H
Reset value: 0000H
15 8
Not used
7 0
Not used tim_set2
_en
tim_set2_en Timer set 2 enable
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 168 2003-01-20
7.15 Cell Delineation FSM Status Register (cdfs)
Read only Address 00015H
Reset value: 0000H
15 8
status_p7[1:0] status_p6[1:0] status_p5[1:0] status_p4[1:0]
7 0
status_p3[1:0] status_p2[1:0] status_p1[1:0] status_p0[1:0]
status_pN Cell Delineation FSM status of port N
XX = When pcfN[p_atm] = 0
00 = Hunt
01 = Presync
10 = Sync
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 169 2003-01-20
7.16 Version Register (vers)
Read only Address 00016H
15 9 8
Not used mtypsel
7 0
ec e1/t1 version[5:0]
mtypsel Microcontroller type select
0 = Microcontroller Interface runs in Intel Mode
1 = Microcontroller Interface runs in Motorola Mode
ec Status of EC pin
0 = Echo Cancellation mode(EC)
1 = Normal operation mode
e1/t1 Status of E1/T1 pin
0 = T1 mode
1 = E1 mode
version Version of IWE8
Value of 011 010B for Version 3.2
Value of 011 011B for Version 3.3
Value of 011 100B for Version 3.4
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 170 2003-01-20
7.17 Clock Monitor Register (ckmo)
Read only Address 00017H
Reset value: 0000H
15 8
Not used
7 0
frclk_failure[7:0]
frclk_failure FRCLK clock failure on port N
Bit remains active only as long as a clock failure on FRCLK is detected.
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 171 2003-01-20
7.18 Interrupt Status Register 1 (isr1)
Read only, Address 00018H
Reset value: 0000H
15 8
iq_ne eis4 eis3 eis2 eis1 eis0 Not used
7 0
Not used ut_soc ut_par ex_par crv_par oq_ovf eq_ovf ck_eme
iq_ne Interrupt queue not empty
0 = False
1 = True
eis4 A bit is set in eis4
0 = False
1 = True
eis3 A bit is set in eis3
0 = False
1 = True
eis2 A bit is set in eis2
0 = False
1 = True
eis1 A bit is set in eis1
0 = False
1 = True
eis0 A bit is set in eis0
0 = False
1 = True
ut_soc UTOPIA start of cell error,
indicates if SOC is activated too late or twice within one cell cycle.
(corresponds to transmit direction in slave mode and receive direction in
master mode).
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 172 2003-01-20
Note: Bits 6:0 are used for tracing error events. They are set on the occurrence of an
error event and reset by a microprocessor read operation.
Bits 15:10 Bits are reset upon reading of the interrupt generating register.
ut_par Parity error on UTOPIA bus
ex_par Parity error on external RAM
In order to prevent external RAM parity errors, the external RAM should
be written completely during board initialization by the microprocessor.
0 = False
1 = True
crv_par Parity error on clock recovery interface
0 = False
1 = True
oq_ovf Output queue overflow
0 = False
1 = True
eq_ovf Error queue overflow
0 = False
1 = True
ck_eme Emergency mode state change on one of the emergency mode enabled
ports (see ckmo)
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 173 2003-01-20
7.19 Extended Interrupt Status 1 Register (eis1)
Destructive read Address 00019H
Reset value: 0000H
15 8
Not used
7 0
Not used cf_fifo_
n_empty
cf_fifo_
full
cf_fifo_full Cell filter FIFO full
0 = False
1 = True
cf_fifo_n_
empty
Cell filter FIFO not empty
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 174 2003-01-20
7.20 Extended Interrupt Status 2 Register (eis2)
Destructive read Address 0001AH
Reset value: 0000H
15 8
Not used
7 0
rts_overflow[7:0]
rts_overflow RTS buffer overflow of IWE core at port N
Applicable for AAL ports in unstructured CES mode with SRTS.
X = When pcfN[p_atm] = 1 or pcfN[p_ces] = 0 or pcfN[p_srts] = 0
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 175 2003-01-20
7.21 Extended Interrupt Status 3 Register (eis3)
Destructive read Address 0001BH
Reset value: 0000H
15 8
Not used
7 0
tim_set1_exp[7:0]
tim_set1_
exp
Timer of set 1 expired
Each bit indicates if the corresponding timer expired
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 176 2003-01-20
7.22 Extended Interrupt Status 4 Register (eis4)
Destructive read Address 0001CH
Reset value: 0000H
15 8
ocd_end[7:0]
7 0
ocd_start[7:0]
ocd_end End of OCD (Out of cell delineation) state at port N
X = When pcfN[p_atm] = 0
0 = False
1 = True
ocd_start Start of OCD (Out of cell delineation) state at port N
X = When pcfN[p_atm] = 0
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 177 2003-01-20
7.23 Interrupt Status Register 2 (isr2)
Destructive read Address 0001DH
Reset value: 0000H
t
15 8
Not used
7 0
tim_set2_exp[7:0]
tim_set2_
exp
Timer of timer set 2 expired
Each bit indicates if the corresponding timer expired
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 178 2003-01-20
7.24 Operation Mode Register (opmo)
Read/write Address 0001EH
Reset value 1100H
15 8
Not used symn rts_gen rts_eval bufthr[3:1]
7 0
bufthr0 tfpp rfpp ftri frri om[1:0] cbb
symn SYMn mode
This bit is relevant only in SYM2 and SYM8
0 = FRMFB[0] is used for frame and multiframe synchronization in
receive and transmit direction of all ports. FRMFB[1:7] are
unused
1 = FRMFB[N] is used for frame and multiframe synchronization in
receive and transmit direction of corresponding ports
rts_gen RTS generation
0 = Pin SDI is used for RTS
1 = RTS data are generated by ICRC
rts_eval RTS evaluation
0 = Pins FTCKO are used as transmit clock (all FTCKO[0:7] are input
pins)
1 = Clock of ICRC is used as transmit clock and is also switched to
FTCKO pins (FTCKO[0:7] all are output pins)
bufthr Buffer threshold
Determines the threshold for the ATM Transmit Buffer. If the buffer level
remains under the threshold the signal ATBTC will be activated.
tfpp Transmit frame pulse polarity
valid for GIM
0 = FTMFS is active low
1 = FTMFS is active high
rfpp Receive frame pulse polarity
valid for GIM, SYM8 and SYM2
0 = FRMFB is active low
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 179 2003-01-20
1 = FRMFB is active high
ftri Framer transmit rising edge
valid for GIM
0 = FTDAT outputs are clocked with the falling edge of FTCKO
1 = FTDAT outputs are clocked with the rising edge of FTCKO
frri Framer receive rising edge
valid for GIM:
0 = FRDAT inputs are sampled with the falling edge of FRCLK
1 = FRDAT inputs are sampled with the rising edge of FRCLK
valid for SYM2:
0 = FRDAT inputs are sampled with the falling edge of RFCLK
FTDAT outputs are clocked with the rising edge of RFCLK
1 = FRDAT inputs are sampled with the rising edge of RFCLK
FTDAT outputs are clocked with the falling edge of RFCLK
om Operation Mode
00 = FAM: FALC mode
FTCKO and FRCLK running at 8.192 MHz
01 = GIM: Generic Interface mode1)
FTCKO and FRCLK running at 2.048 (E1) or 1.544 (T1) MHz
10 = SYM8: E1 synchronous mode (RFCLK = 8.192 MHz)
11 = SYM2: E1 synchronous mode (RFCLK = 2.048 MHz)
cbb Clock Boost Bypass
0 = Normal operation: the external clock at RFCLK in internally
doubled to serve as reference clock for the internal DPLL
1 = Clock boost function bypassed
1) Make sure that no clocks are applied to the transmitter when switching to GIM.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 180 2003-01-20
7.25 FT Clock Select Register (ftcs)
Read/write Address 0001FH
Reset value 0000H
Note: Register opmo has to be set before ftcs is configured.
15 8
ftck7[1:0] ftck6[1:0] ftck5[1:0] ftck4[1:0]
7 0
ftck3[1:0] ftck2[1:0] ftck1[1:0] ftck0[1:0]
ftckiClock Source for framer transmit interface
valid for FAM and GIM
00 = FTCKOi if opmo[rts_eval]=0
Recovered Clock of ICRC if opmo[rts_eval] = 1
01 = FRCLKi (opmo[rts_eval] = 1 is required)
10 = Derived from RFCLK (opmo[rts_eval] = 1 is required)
11 = No clock
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 181 2003-01-20
7.26 Cell Filter VCI Pattern 1 Register (cfvp1)
Read/write Address 20H
Reset value: 0000H
15 8
vci_pattern1[15:8]
7 0
vci_pattern1[7:0]
vci_pattern1 First VCI pattern the cell header is compared with.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 182 2003-01-20
7.27 Cell Filter VCI Mask 1 Register (cfvm1)
Read/write Address 00021H
Reset value: 0000H
15 8
vci_mask1[15:8]
7 0
vci_mask1[7:0]
vci_mask1 Each bit masks the corresponding bit in cfvp1
0 = Not masked
1 = Masked
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 183 2003-01-20
7.28 Cell Filter VCI Pattern 2 Register (cfvp2)
Read/write Address 00022H
Reset value: 0000H
15 8
vci_pattern2[15:8]
7 0
vci_pattern2[7:0]
vci_pattern2 Second VCI pattern the cell header is compared with.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 184 2003-01-20
7.29 Cell Filter VCI Mask 2 Register (cfvm2)
Read/write Address 00023H
Reset value: 0000H
15 8
vci_mask2[15:8]
7 0
vci_mask2[7:0]
vci_mask2 Each bit masks the corresponding bit in cfvp2
0 = Not masked
1 = Masked
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 185 2003-01-20
7.30 Cell Filter Payload Type Register (cfpt)
Read/write Address 00024H
Reset value: 0000H
15 8
Not used pt_pattern2[2:0] pt_mask
2[2]
7 0
pt_mask2[1:0] pt_pattern1[2:0] pt_mask1[2:0]
pt_mask1 Each bit masks the corresponding bit in pt_pattern1.
0 = Not masked
1 = Masked
pt_pattern1 First PT pattern the cell header is compared with.
pt_mask2 Each bit masks the corresponding bit in pt_pattern2.
0 = Not masked
1 = Masked
pt_pattern2 Second PT pattern the cell header is compared with.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 186 2003-01-20
7.31 Command Register (cmd)
Read/write Address 00025H
Reset value 0000H
15 8
Not used
7 0
Not used insert_
cell
pt2_
comp
pt1_
comp
vci2_
comp
vci1_
comp
vci1_comp VCI comparison corresponding to register cfvp1 and cfvm1.
0 = Disabled
1 = Enabled
vci2_comp VCI comparison corresponding to register cfvp2 and cfvm2.
0 = Disabled
1 = Enabled
pt1_comp PT comparison corresponding to fields pt_pattern1 and pt_mask1 in
register cfpt.
0 = Disabled
1 = Enabled
pt2_comp PT comparison corresponding to fields pt_pattern2 and pt_mask2 in
register cfpt.
0 = Disabled
1 = Enabled
insert_cell Cell insertion via microprocessor.
A cell will be inserted in the data stream as soon as possible; when
finished this bit will be reset.
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 187 2003-01-20
7.32 Cell Filter Read Pointer Register (cfrp)
Read/write Address 00026H
Reset value 0002H
15 8
Not used
7 0
rdptr[7:0]
rdptr Read Pointer for the Cell Extraction Buffer
02H
to
FFH
This value is a pointer to the current address, at which the
microprocessor will read the next extracted cell from the Cell
Extraction Buffer
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 188 2003-01-20
7.33 Threshold Register (thrshld)
Read/write Address 00027H
Reset value 00FFH
15 8
Not used
7 0
threshold[7:0]
threshold Global ATM transmit buffer threshold for discarding cells
00H
to
FFH
If the amount of cells stored in the ATM transmit buffer crosses
this value cells will be discarded.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 189 2003-01-20
7.34 UTOPIA Configuration Register (utconf)
Read/write Address 00028H
Reset value 0001H
15 8
Not used utrange[2:0] utprtyen utbaseadr[4:3]
7 0
utbaseadr[2:0] utlevel utmaster mapping_mode[2:0]
utrange UTOPIA Port Range
Controls the supported port range if the device is configured as UTOPIA
level 2 PHY-Layer (utlevel=0, utmaster=0, mapping_mode=000B)
000 = Ports 0 to 7 enabled
001 = Port 0 enabled
010 = Ports 0 and 1 enabled
011 = Ports 0 to 2 enabled
100 = Ports 0 to 3 enabled
101 = Ports 0 to 4 enabled
110 = Ports 0 to 5 enabled
111 = Ports 0 to 6 enabled
utprtyen UTOPIA parity check enable
0 = Disabled
1 = Enabled
utbaseadr UTOPIA base address
Defines the base address under which the PHY-Layer is accessible.
User has to set this value to 0 if device utlevel = 1.
utlevel UTOPIA interface level
In Master mode only UTOPIA level 1 is available.
0 = UTOPIA level 2
1 = UTOPIA level 1
utmaster UTOPIA Slave/Master configuration
0 = Slave mode (PHY-Layer)
1 = Master mode (ATM-Layer)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 190 2003-01-20
mapping
_mode
Mapping of the “port_nr” associated with the currently transferred cell
into the UTOPIA datastream
000 = Disabled
001 = Mapping to UDF[2:0] field in ATM header
010 = Mapping toVCI[7:5] field in ATM header
011 = Mapping toVCI[15:13] field in ATM header
100 = Mapping toVPI[7:5] field in ATM header
101 = Mapping toGFC[3:1] field in ATM header
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 191 2003-01-20
7.35 CAS 1 Register (cas1)
Read/write Address 00029H
Reset value: BBBBH
15 8
cas0port3[3:0] cas0port2[3:0]
7 0
cas0port1[3:0] cas0port0[3:0]
cas0port0 E1 CAS frame 0 pattern for port 0 (unused in T1 mode)
cas0port1 E1 CAS frame 0 pattern for port 1 (unused in T1 mode)
cas0port2 E1 CAS frame 0 pattern for port 2 (unused in T1 mode)
cas0port3 E1 CAS frame 0 pattern for port 3 (unused in T1 mode)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 192 2003-01-20
7.36 CAS 2 Register (cas2)
Read/write Address 0002AH
Reset value: BBBBH
15 8
cas0port7[3:0] cas0port6[3:0]
7 0
cas0port5[3:0] cas0port4[3:0]
cas0port4 E1 CAS frame 0 pattern for port 4 (unused in T1 mode)
cas0port5 E1 CAS frame 0 pattern for port 5 (unused in T1 mode)
cas0port6 E1 CAS frame 0 pattern for port 6 (unused in T1 mode)
cas0port7 E1 CAS frame 0 pattern for port 7 (unused in T1 mode)
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 193 2003-01-20
7.37 CAS 3 Register (cas3)
Read/write Address 0002BH
Reset value: 000DH
15 8
Not used
7 0
Not used cas_idle
cas_idle CAS idle pattern for unused timeslots of the Tx frame
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 194 2003-01-20
7.38 Threshold Register for Ports 0 and 1 (thrsp01)
Read/write Address 0002CH
Reset value: FFFFH
15 8
p_odd[7:0]
7 0
p_even[7:0]
p_odd Port 1 threshold for backpressure of UTOPIA Tx
p_even Port 0 threshold for backpressure of UTOPIA Tx
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 195 2003-01-20
7.39 Threshold Register for Ports 2 and 3 (thrsp23)
Read/write Address 0002DH
Reset value: FFFFH
15 8
p_odd[7:0]
7 0
p_even[7:0]
p_odd Port 3 threshold for backpressure of UTOPIA Tx
p_even Port 2 threshold for backpressure of UTOPIA Tx
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 196 2003-01-20
7.40 Threshold Register for Ports 4 and 5 (thrsp45)
Read/write Address 02EH
Reset value: FFFFH
15 8
p_odd[7:0]
7 0
p_even[7:0]
p_odd Port 5 threshold for backpressure of UTOPIA Tx
p_even Port 4 threshold for backpressure of UTOPIA Tx
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 197 2003-01-20
7.41 Threshold Register for Ports 6 and 7 (thrsp67)
Read/write Address 0002FH
Reset value: FFFFH
15 8
p_odd[7:0]
7 0
p_even[7:0]
p_odd Port 7 threshold for backpressure of UTOPIA Tx
p_even Port 6 threshold for backpressure of UTOPIA Tx
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 198 2003-01-20
7.42 Extended Interrupt Status 0 Register (eis0)
Destructive Read Address 00030H
Reset value: 0000H
15 8
lcd_end[7:0]
7 0
lcd_start[7:0]
lcd_end End of LCD detect on port N
0 = False
1 = True
lcd_start Start of LCD detect on port N
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 199 2003-01-20
7.43 LCD Timer Register (lcdtimer)
Read/write Address 00031H
Reset value: FFFFH
15 8
lcd_val[14:7]
7 0
lcd_val[6:0] lcd_dis
lcd_val LCD timer preload value
The port specific LCD timer is pre-loaded with 128 * lcd_val and clocked
with CLOCK. After expiration an interrupt is issued in eis0.
lcd_dis LCD timer disable
0 = Enabled
1 = Disabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 200 2003-01-20
7.44 Interrupt Source Register (irs)
Read only Address 00101H
Reset value: 0000H
Bits are reset after reading the corresponding registers.
15 8
Not used irs7 irs6 irs5
7 0
irs4 irs3 irs2 irs1 irs0 crifo scri per
irsN IRS register of port N
These bits indicate if a bit is set in irsN
0 = False
1 = True
crifo Clock recovery interface FIFO overflow
This bit indicates if a bit is set in crifo
0 = False
1 = True
scri Synchronization errors at the internal clock recovery interface
This bit indicates if a bit is set in scri
0 = False
1 = True
per Parity errors at the clock recovery interface.
This bit indicates if a bit is set in per
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 201 2003-01-20
7.45 Interrupt Mask (irm)
Read/Write Address 00102H
Reset value: 07FFH
15 8
Not used irm7 irm6 irm5
7 0
irm4 irm3 irm2 irm1 irm0 crifo scri per
irmN Each bit masks the corresponding irsN in irs
0 = Not masked
1 = Masked
crifo This bit masks the bit crifo in irs
0 = Not masked
1 = Masked
scri This bit masks the bit scri in irs.
0 = Not masked
1 = Masked
per This bit masks the bit per in irs
0 = Not masked
1 = Masked
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 202 2003-01-20
7.46 Internal Clock Recovery Circuit Configuration Register
(icrcconf)
Read/Write Address 00103H
Reset value: 0020H
15 8
Not used gim
7 0
ds1 parc pdcri srst lptd lptu lprd lpru
gim Generic interface mode
0 = FAM: 8.192 MHz is expected/generated.
1 = GIM: 2.048 MHz (E1) or 1.544 MHz (T1) expected/generated.
ds1 DS1 Mode
0 = E1: The receive clocks are divided to 2.048 MHz. Output clocks
are 8.192 MHz in case of FAM or 2.048 MHz in case of GIM.
1 = T1: The receive clocks are divided to 1.544 MHz. Output clocks
are 8.192 MHz in case of FAM or 1.544 MHz in case of GIM.
parc Parity Check
Inverts all parity bits in the ICRC. All enabled parity checkers will
generate interrupts
0 = Disabled
1 = Enabled
pdcri Power Down Clock Recovery Interface
0 = Normal operation
1 = The internal clock recovery interface is put in power down mode.
No data is received, no errors are generated and the parity check
is disabled.
srst Software Reset
The bit srst is set by the software, but reset by the ICRC. Reading this
bit will always give the Reset value: “0”.
0 = Normal operation
1 = Reset ICRC
lptd Loop back clock recovery interface transmitted data downstream
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 203 2003-01-20
0 = Disabled
1 = Enabled
lptu Loop back clock recovery interface transmitted data upstream
0 = Disabled
1 = Enabled
lprd Loop back clock recovery interface received data downstream
0 = Disabled
1 = Enabled
lpru Loop back clock recovery interface received data upstream
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 204 2003-01-20
7.47 Configuration Register Downstream of Port N (condN)
Read/Write Address 00104H + N x 32
Reset value: 0840H
15 8
not used tur[5:1]
7 0
tur(0] pwd lgc lc8 lgs lpcr srt acm
tur Tuning range select of port N
The tuning range of PLL-ACM is limited to:
(frequency deviation of pin RFCLK in ppm) +/- ((4*tur) +/-5%)ppm.
pwd Power down of port N
0 = Normal operation
1 = Power down mode. No RTS values and no transmit clock are
generated.
lgc Loop back generated clock
0 = Normal operation
1 = The clock generated by the PLL is looped into the RTS generator.
lc8 Loop back clock 8.192 MHz
0 = Normal operation
1 = The receive clock is looped to the transmit output of the ICRC.
lgs Loop back generated RTS
0 = Normal operation
1 = Generated RTS values are looped into the SRTS Receive FIFO.
lpcr Loop back clock recovery Interface
0 = Normal operation
1 = The clock recovery interface is bypassed. RTS values from the
frame receiver are looped into the SRTS Transmit FIFO.
srt, acm Selectors for the clock generation algorithm
00 = The PLL is put in power down mode, and a free running clock is
generated. In case pwd is set, all circuits of the port, including the
RTS generator are disabled, no output clock is generated and all
error counters are reset.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 205 2003-01-20
01 = Transmit clock generation of this port is based on the adaptive
clock algorithm
10 = Transmit clock generation of this port is based on the SRTS
algorithm.
11 = Transmit clock generation of this port is based on both
algorithms. The tuning range of PLL-ACM can not be reduced
(tur), because PLL-ACM has to accept the jitter passed through
or generated in PLL-SRTS.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 206 2003-01-20
7.48 Interrupt Source of Port N (irsN)
Read only Address 00105H + N x 32
Reset value: 0000H
Bits are reset upon reading of the interrupt generating register.
15 8
not used
7 0
not used srrn tsoutn srun sron srin atln ooln
srrn A bit is set in srrn.
0 = False
1 = True
tsoutn A bit is set in tsoutN.
0 = False
1 = True
srun A bit is set in sruN
0 = False
1 = True
sron A bit is set in sroN.
0 = False
1 = True
srin A bit is set in sriN.
0 = False
1 = True
atln A bit is set in atlN.
0 = False
1 = True
ooln A bit is set in oolN.
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 207 2003-01-20
7.49 Interrupt Mask of Port N (irmN)
Read/Write Address 00106H + N x 32
Reset value: 007FH
15 8
not used
7 0
not used srrn tsoutn srun sron srin atln ooln
srrn This bit masks the bit srrN in irsN
0 = Not masked
1 = Masked
tsoutn This bit masks the bit tsoutN in irsN
0 = Not masked
1 = Masked
srun This bit masks the bit sruN in irsN.
0 = Not masked
1 = Masked
sron This bit masks the bit sroN in irsN
0 = Not masked
1 = Masked
srin This bit masks the bit sriN in irsN
0 = Not masked
1 = Masked
atln This bit masks the bit atlN in irsN
0 = Not masked
1 = Masked
ooln This bit masks the bit oolN in irsN
0 = Not masked
1 = Masked
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 208 2003-01-20
7.50 Test Input of Port N (tsinN)
Read/Write Address 00107H + N x 32
Reset value: 0000H
Successive writes to this register should have a minimum distance of 8 x 32 x TCLOCK.
This is the (maximum) time needed to transmit the value rtsi to the clock recovery. In
case bit lgs of register condN is set, this waiting time is not necessary.
15 8
not used
7 0
not used rtsi[3:0] ena
rtsi RTS Input value of port N
ena Test Input Enable
Disconnect the RTS generator from the transmit FIFO. Each write
command to this register injects the value rtsi into the transmit FIFO.
0 = Disabled
1 = Enabled:
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 209 2003-01-20
7.51 Configuration Register Upstream Direction of Port N (conuN)
Read/Write Address 00108H + N x 32
Reset value: 0000H
.
15 8
not used
7 0
not used rtsg
rtsg RTS generator enable
0 = Disabled
1 = Enabled
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 210 2003-01-20
7.52 Average Buffer Filling of Port N (avbN)
Read/Write Address 0010CH + N x 32
Reset value: 2000H
15 8
not used avb[13:8]
7 0
avb[7:0]
avb Average buffer filling of port N
This field defines the number of bytes ACM should try to keep in the data
buffer of the clock recovery. This value should correspond with the
number of bytes the clock recovery initially stores in the data buffer.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 211 2003-01-20
7.53 ACM Shift Factor of Port N (asfN)
Read/Write Address 0010DH + N x 32
Reset value: 0000H
15 8
not used
7 0
not used dir ampl[2:0]
dir Direction of shifting
0 = shift left = amplification
1 = shift right = attenuation
ampl Amplitude of shifting
This defines the loop-gain of PLL-ACM. It is equivalent to a multiplication
with (or a division by) 2ampl.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 212 2003-01-20
7.54 Time of Initial Free Run of Port N (tiniN)
Read/Write Address 0010EH + N x 32
Reset value: 0400H
15 8
not used tini[12:8]
7 0
tini[7:0]
tini[12:0] Time of initial free run of port N
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 213 2003-01-20
7.55 Threshold Out of Lock Detection of Port N (tresh)
Read/Write Address 0010FH + N x 32
Reset value: 0111H
15 8
not used tr_filt[3:0]
7 0
tr_srts[3:0] tr_acm[3:0]
tr_filt Threshold for out of lock detection of PLL-FILTER
If more than tr_filt out of lock detections during 16 SRTS periods (128
ATM cells) are made, oolN[olf] is set
tr_srts Threshold for out of lock detection of PLL-SRTS
If more than tr_srts out of lock detections during 16 SRTS periods (128
ATM cells) are made, oolN[ols] is set
tr_acm Threshold for out of lock detection of PLL-ACM
If more than tr_acm out of lock detections during 16 ATM cells are made,
oolN[ola] is set.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 214 2003-01-20
7.56 ICRC Parity Errors at Clock Recovery Interface (per)
Destructive read Address 00110H
Reset value: 0000H
Note: A synchronization error (scri) generates a random number of parity errors
15 8
perd[7:0]
7 0
peru[7:0]
perd Parity Errors at the Clock Recovery Interface Downstream Pin SDOD
This field counts the amount of parity errors at the internal clock recovery
interface. In case there are more than 255 errors, the value is kept
peru Parity Errors at the Clock Recovery Interface Upstream Pin SDI
This field counts the amount of parity errors at the internal clock recovery
interface. In case there are more than 255 errors, the value is kept
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 215 2003-01-20
7.57 ICRC Synchronization Errors at Clock Recovery Interface (scri)
Destructive read Address 00111H
Reset value: 0000H
Note: A synchronization error (scri) generates a random number of parity errors (per)
15 8
not used
7 0
scri[7:0]
scri Synchronization Error at the Clock Recovery Interface
This field counts the amount of synchronization errors at the internal
clock recovery interface. In case there are more than 255 errors, the
value is kept
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 216 2003-01-20
7.58 ICRC Clock Recovery Interface FIFO Overflow (crifo)
Destructive read Address 00112H
Reset value: 0000H
15 8
not used
7 0
crifo[7:0]
crifo Clock Recovery Interface FIFO Overflow
This field counts the number of times the SRTS transmit FIFO overflows.
In case there are more than 255 errors, the value is kept
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 217 2003-01-20
7.59 ICRC Version Register (icrcv)
Read only Address 00113H
Reset value: 0034H
Note: The version and release number are defined as: IWE8 V<ver>.<rel>
15 8
not used
7 0
not used ver[2:0] rel[2:0]
ver Version Number
rel Release Number
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 218 2003-01-20
7.60 SRTS Receive FIFO Underflow of Port N (sruN)
Destructive read Address 00114H + N x 32
Reset value: 0000H
15 8
not used
7 0
sru[7:0]
sru SRTS Receive FIFO underflow of port N
This field counts the amount of underflows of the SRTS Receive FIFO.
Upon reaching FFH it keeps its value.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 219 2003-01-20
7.61 SRTS Receive FIFO Overflow of Port N (sroN)
Destructive read Address 00115H + N x 32
Reset value: 0000H
15 8
not used
7 0
sro[7:0]
sro SRTS Receive FIFO overflow of port N
This field counts the amount of overflows of the SRTS Receive FIFO.
Upon reaching FFH it keeps its value.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 220 2003-01-20
7.62 SRTS Generator Reset of Port N (srrN)
Destructive read Address 00116H + N x 32
Reset value: 0000H
15 8
not used
7 0
srr[7:0]
srr SRTS generator reset command counter of port N
This field counts the number of times the SRTS generator is reset by
frame receiver 1. Upon reaching FFH it keeps its value.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 221 2003-01-20
7.63 SRTS Invalid Value Processed of Port N (sriN)
Destructive read Address 00117H + N x 32
Reset value: 0000H
15 8
not used
7 0
sri[7:0]
sri SRTS invalid value processed counter of port N
This field counts the number of times PLL-SRTS and PLL-FILTER went
in hold over due to invalid RTS values. Upon reaching FFH it keeps its
value.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 222 2003-01-20
7.64 ACM Data Too Late of Port N (atlN)
Destructive read Address 00118H + N x 32
Reset value: 0000H
15 8
not used
7 0
atl[7:0]
atl ACM data too late error counter of port N
This field counts the number of times the next ACM data arrived more
than 10 ms too late. Upon reaching FFH it keeps its value.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 223 2003-01-20
7.65 Out Of Lock Register of Port N (oolN)
Destructive read Address 00119H + N x 32
Reset value: 0000H
15 8
not used
7 0
not used olf ols ola
olf PLL-Filter out of lock at port N
This bit indicates that the number of times PLL-FILTER went out of lock
exceeds treshN[tr_filt].
0 = False
1 = True
ols PLL-SRTS out of lock at port N
This bit indicates that the number of times PLL-SRTS went out of lock
exceeds treshN[tr_srts].
0 = False
1 = True
ola PLL-ACM out of lock at port N
This bit indicates that the number of times PLL-ACM went out of lock
exceeds treshN[tr_acm].
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 224 2003-01-20
7.66 Status Register of Port N (statN)
Destructive read Address 0011AH + N x 32
Reset value: 0001H
15 8
not used
7 0
not used max hov frr
max Maximum frequency deviation
Indicates that PLL-ACM is clipped at its maximum frequency deviation.
0 = False
1 = True
hov Hold over
Indicates that PLL-SRTS is put in hold over because of error conditions
in the SRTS processing.
0 = False
1 = True
frr Free running clock
Indicates that PLL-SRTS or PLL-ACM is put in free run during start-up.
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Register Description
Data Sheet 225 2003-01-20
7.67 Test Output Register of Port N (tsoutN)
Destructive read Address 0011BH + N x 32
Reset value: 0000H
Note: By verifying bit dav, the SRTS Receive FIFO can be read completely by
successive reads of this register.
15 8
not used
7 0
not used rtso[3:0] dav
rtso RTS test output value of port N
If bit ena from register tsinN is set: RTS value at the output of the SRTS
Receive FIFO of this port.
dav Data available
SRTS Receive FIFO of this port is not empty
0 = False
1 = True
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 226 2003-01-20
8 Application Hints
8.1 Clock Concept
Figure 38 Clock Concept
E1
/
T1
Fra-
mer
Inter-
face
Clock
Reco-
very om ftcki
rts_
eval RFCLK FRCLK[0:7] FTCKO[0:7] CLK52 CLOCK
RXCLK
TXCLK
E1 FAM none 00 00 00 32.768 MHz OEC 8.192 MHz 8.192 MHz unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 FAM none 00 01 01 32.768 MHz OEC 8.192 MHz FRCLK[0:7] unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 FAM none 00 10 01 32.768 MHz 8.192 MHz unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 FAM SRTS 00 00 01 32.768 MHz +/- 50ppm 8.192 MHz 8.192 MHz from ICRC 51.84 MHz +/- 250ppm 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 FAM ACM 00 00 01 32.768 MHz +/- 130ppm 8.192 MHz 8.192 MHz from ICRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 FAM ECRC 00 00 00 32.768 MHz OEC 8.192 MHz 8.192 MHz from ECRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 GIM none 01 00 00 32.768 MHz OEC 2.048 MHz 2.048 MHz unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 GIM none 01 01 01 32.768 MHz OEC 2.048 MHz FRCLK[0:7] unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 GIM none 01 10 01 32.768 MHz 2.048 MHz RFCLK / 16 unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 GIM SRTS 01 00 01 32.768 MHz +/- 50ppm 2.048 MHz 2.048 MHz from ICRC 51.84 MHz +/- 250ppm 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 GIM ACM 01 00 01 32.768 MHz +/- 130ppm 2.048 MHz 2.048 MHz from ICRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 GIM ECRC 01 00 00 32.768 MHz OEC 2.048 MHz 2.048 MHz from ECRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 SYM8 none 10 x x 8.192 MHz FIC unused unused unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 SYM2 none 11 x x 2.048 MHz FIC unused unused unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
E1 EC none x x x 8.192 MHz FIC unused unused unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 FAM none 00 00 00 32.768 MHz OEC 8.192 MHz 8.192 MHz unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 FAM none 00 01 01 32.768 MHz OEC 8.192 MHz FRCLK[0:7] unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 FAM none 00 10 01 32.768 MHz 8.192 MHz unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 FAM SRTS 00 00 01 32.768 MHz +/- 50ppm 8.192 MHz 8.192 MHz from ICRC 51.84 MHz +/- 250ppm 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 FAM ACM 00 00 01 32.768 MHz +/- 130ppm 8.192 MHz 8.192 MHz from ICRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 FAM ECRC 00 00 00 32.768 MHz OEC 8.192 MHz 8.192 MHz from ECRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 GIM none 01 00 00 24.704 MHz OEC 1.544 MHz 1.544 MHz unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 GIM none 01 01 01 24.704 MHz OEC 1.544 MHz FRCLK[0:7] unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 GIM none 01 10 01 24.704 MHz 1.544 MHz RFCLK / 16 unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 GIM SRTS 01 00 01 24.704 MHz +/- 50ppm 1.544 MHz 1.544 MHz from ICRC 51.84 MHz +/- 250ppm 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 GIM ACM 01 00 01 24.704 MHz +/- 130ppm 1.544 MHz 1.544 MHz from ICRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 GIM ECRC 01 00 00 24.704 MHz OEC 1.544 MHz 1.544 MHz from ECRC unused 12*FDATA < FCLOCK < 39MHz <= CLOCK
T1 SYM8 none 10 x x unused unused unused unused unused unused
T1 SYM2 none 11 x x unused unused unused unused unused unused
T1 EC none x x x unused unused unused unused unused unused
BITS
(
cbb=0
)
PINSMode
FIC = Framer Interface Clock for Rx and Tx; OEC = Optional Emergency Clock; x = Don't care; ECRC = External Clock Recovery Circuit;
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 227 2003-01-20
The PLLs for SRTS accept RFCLK deviations of at least + and - 50 ppm. However, in
case of switchover to emergency mode, RFCLK will be used to generate the line clock,
which has to fulfill specifications like "maximum 4.6 ppm deviation under ALL
circumstances". In this case RFCLK accuracy has to be 4.6 ppm.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 228 2003-01-20
8.2 Translating AAL Statistics Counters into the ATMF CES Version
2 MIB
Reset Statistics Counters and µP RAM variables before connection setup
atmfCESReassCells
Accumulated values from IWE8 Statistics Counter #2 destructive read accesses
atmfCESHdrErrors
Accumulated values from IWE8 Statistics Counter #6 destructive read accesses
atmfCESPointerReframes
CES Version 2.0 MIB recommends "This records the count of the number of events in
which the AAL1 reassembler found that an SDT pointer is not where it is expected, and
the pointer must be reacquired.“
"Pointer is not where it is expected" can mean.
a) no pointer occurs within an 8-cell-cycle
b) two pointers occur within an 8-cell-cycle
c) pointer is not in the 2nd byte of ATM cell payload,
Error case a) and b) causes incrementation of Statistics Counter #11.
All error cases a), b) and c) causes loss of synchronization of AtmStartOfStructure (IWE8
reassembly buffer read pointer to structure start in ATM cell) with PortStartOfStructure
(pointer to structure start in framer interface port), so that Statistics Counter #14
increments.
==> Accumulated values from IWE8 Statistics Counter #14 destructive read accesses.
atmfCESPointerParityErrors
Accumulated values from IWE8 Statistics Counter #10 destructive read accesses
atmfCESAal1SeqErrors
Accumulated values from IWE8 Statistics Counter #7 destructive read accesses
atmfCESLostCells
Accumulated values from IWE8 Statistics Counter #15 destructive read accesses
atmfCESMisinsertedCells
Accumulated values from IWE8 Statistics Counter #8 destructive read accesses
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 229 2003-01-20
atmfCESBufUnderflows
Can be derived from IWE8 Statistics Counter #13
atmfCESBufOverflows
Can be derived from IWE8 Statistics Counter #4
atmfCESCellLossStatus
Can be derived from atmfCESBufUnderflows and EndOfUnderflow
"When cells are continuously lost for the number of milliseconds specified by
atmfCESCellLossIntegrationPeriod, the value is set to loss (2). When cells are no longer
lost, the value is set to noLoss (1).“
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 230 2003-01-20
8.3 Jitter Characteristics of the Internal Clock Recovery Circuit
This section shows the results of jitter analysis of the ICRC. The device is intended to be
used with an external jitter attenuator. For this purpose Infineon’s FALC-LH was used.
Results are shown with and without jitter attenuator. Measurements were done using a
Wandel & Goltermann ANT20 for IWE8 in T1 mode with FALC-LH and Wandel &
Goltermann PFJ-8 for the bare IWE8 in E1 or T1 mode.
8.3.1 ACM Jitter Tolerance in E1 Mode
The jitter tolerance falls with 20 dB per decade, It is independent from the PLL gain
("ASF").
For the bare device the jitter tolerance meets the requirements of ITU-T G.823 and I.431
at medium and low frequencies. At frequencies lower than 1 KHz the jitter tolerance is
more than 20 UI. At high frequencies it is lower than the requirements.
In combination with an jitter attenuator the requirements are met. Jitter tolerance at high
frequencies is better than 0.2 UI.
Figure 39 ACM Jitter Tolerance in E1 Mode without Jitter Attenuator
ACM Jitter Tolerance in E1 mode, CDV=0, ASF=4
0,1
1,0
10,0
100,0
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jitter [UI]
-50 ppm
0 ppm
+50 ppm
ITU G. 823
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 231 2003-01-20
Figure 40 ACM Jitter Tolerance in E1 Mode with Jitter Attenuator
8.3.2 ACM Jitter Tolerance in T1 Mode
The jitter tolerance of the bare device in T1 mode exceeds the capabilities of the
measurement equipment. This behavior is independent from frequency offset or PLL
gain.
Using the jitter attenuator slightly reduces the jitter tolerance to a level which can be
measured. All requirements are fulfilled.
E1, ACM, FALC jitter tolerance, CDV=0, ASF=4
0,1
1,0
10,0
100,0
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jitter [UI]
-50 ppm
0 ppm
+50 ppm
ITU G.823
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 232 2003-01-20
Figure 41 ACM Jitter Tolerance in T1 Mode without Jitter Attenuator
Figure 42 ACM Jitter Tolerance in T1 Mode with Jitter Attenuator
ACM Jitter Tolerance in T1 mode, CDV=0, ASF=4
0,1
1
10
100
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jitter [UI]
ITU G.824 and
I.431
TR-NWT-499
Measurement
limitation
ACM Jitter Tolerance in T1 Mode, CDV=0, ASF=4
0,1
1
10
100
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jitter [UI]
-130 ppm
0 ppm
+130 ppm
ITU G.824 and
I.431
TR-NWT-499
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 233 2003-01-20
8.3.3 SRTS Jitter Tolerance in E1 Mode
The aliasing effect which is inherent to the SRTS algorithm causes the jitter tolerance at
681 Hz and all multiples of 681 Hz to be a copy of the jitter tolerance at 0 Hz.
The jitter tolerance of the bare device meets the requirements of ITU-T G.823 and I.431
only at medium and low frequencies. At high frequencies it is lower than the
requirements.
In combination with an jitter attenuator the tolerance at high frequencies is better than
0.2 UI. All requirements are met.
Figure 43 SRTS Jitter Tolerance in E1 Mode without Jitter Attenuator
SRTS Jitter Tolerance in E1 Mode
0,1
1,0
10,0
100,0
1 10 100 1000 10000 100000 1000000 Freqency [Hz]
Jitter [UI]
-50 ppm
0 ppm
+50 ppm
ITU G.823
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 234 2003-01-20
Figure 44 SRTS Jitter Tolerance in E1 Mode with Jitter Attenuator
8.3.4 SRTS Jitter Tolerance in T1 Mode
The aliasing effect which is inherent to the SRTS algorithm causes the jitter tolerance at
513 Hz and all multiples of 513 Hz to be a copy of the jitter tolerance at 0 Hz. Jitter
Tolerance at low frequencies violate the requirements.
With jitter attenuator jitter tolerance at low frequencies is increased and all jitter
frequencies above 20 Hz are removed. As a result no aliasing is possible. The jitter
tolerance fulfills the requirements.
SRTS Jitter Tolerance in E1 Mode
0,1
1
10
100
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jitter [UI]
-50 ppm
0 ppm
+50 ppm
ITU G.823
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 235 2003-01-20
Figure 45 SRTS Jitter Tolerance in T1 Mode without Jitter Attenuator
Figure 46 SRTS Jitter Tolerance in T1 Mode with Jitter Attenuator
SRTS Jitter Tolerance in T1 Mode
0,1
1
10
100
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jiiter [UI]
-130 ppm
0 ppm
+130 ppm
ITU G.824
and I.431
TR-NWT-499
SRTS Jitter Tolerance in T1 Mode
0,1
1
10
100
1 10 100 1000 10000 100000 1000000 Frequency [Hz]
Jitter [UI]
-130 ppm
0 ppm
+130 ppm
ITU G.824
and I.431
TR-NWT-499
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 236 2003-01-20
8.3.5 ACM Jitter Transfer in E1 Mode
The jitter transfer characteristics are much better than the requirements of ITU-T G.735
and I. 432.
The -3dB point of the transfer curve is proportional to the PLL-gain: 0.05 Hz for ASF=4,
0.2 Hz for ASF=16.
No impact of the jitter attenuator on the already very good jitter transfer behavior could
be measured.
Figure 47 ACM Jitter Transfer in E1 Mode without Jitter Attenuator
ACM Jitter Transfer in E1 mode: ASF=4
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
-50 ppm
0 ppm
+50 ppm
ITU G.735
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 237 2003-01-20
Figure 48 ACM Jitter Transfer in E1 Mode with Jitter Attenuator
8.3.6 ACM Jitter Transfer in T1 Mode
The jitter transfer characteristics are much better than the requirements of ITU-T G.735
and I. 432.
The -3dB point of the transfer curve is proportional to the PLL-gain: 0.075 Hz for ASF=4,
0.3 Hz for ASF=16.
The jitter attenuator improves the already very good jitter transfer behavior. At -130 ppm
all jitter is removed.
ACM Jitter Transfer in E1 Mode: ASF=4
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
-50 ppm
0 ppm
+50 ppm
ITU G.735
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 238 2003-01-20
Figure 49 ACM Jitter Transfer in T1 Mode without Jitter Attenuator
Figure 50 ACM Jitter Transfer in T1 Mode with Jitter Attenuator
ACM Jitter Transfer in T1 Mode: ASF=4
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
-130 ppm
0 ppm
+130 ppm
ITU G.735
and I.431
ACM Jitter Transfer in T1 mode: ASF=4
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
0 ppm
+130 ppm
ITU G.735
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 239 2003-01-20
8.3.7 SRTS Jitter Transfer in E1 Mode
The aliasing effect which is inherent to the SRTS algorithm causes the jitter transfer at
681 Hz and all multiples of 681 Hz to be a copy of the jitter transfer at 0 Hz. This violates
the requirements.
The jitter attenuator removes jitter frequencies above 20 Hz. There is no aliasing and the
requirements are met.
Figure 51 SRTS Jitter Transfer in E1 Mode without Jitter Attenuator
SRTS Jitter Transfer in E1 Mode
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
-50 ppm
0 ppm
+50 ppm
ITU G.735
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 240 2003-01-20
Figure 52 SRTS Jitter Transfer in E1 Mode with Jitter Attenuator
8.3.8 SRTS Jitter Transfer in T1 Mode
The aliasing effect which is inherent to the SRTS algorithm causes the jitter transfer at
513 Hz and all multiples of 513 Hz to be a copy of the jitter transfer at 0 Hz. This violates
the requirements.
However, the measurement equipment was not able to measure jitter transfer above 100
Hz and the expected peaking is not measured.
The jitter attenuator removes jitter frequencies above 20 Hz. There is no aliasing and the
requirements are met.
SRTS Jitter Transfer
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
-50 ppm
0 ppm
+50 ppm
ITU G.735
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Application Hints
Data Sheet 241 2003-01-20
Figure 53 SRTS Jitter Transfer in T1 Mode without Jitter Attenuator
Figure 54 SRTS Jitter Transfer in T1 Mode with Jitter Attenuator
SRTS Jitter Transfer
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
-130 ppm
0 ppm
+130 ppm
ITU G.735
and I.431
SRTS Jitter Transfer in T1 Mode
-60,0
-50,0
-40,0
-30,0
-20,0
-10,0
0,0
10,0
0,01 0,1 1 10 100 1000
Frequency [Hz]
Transfer [dB]
0 ppm
+130 ppm
ITU G.735
and I.431
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 242 2003-01-20
9 Electrical Characteristics
9.1 Absolute Maximum Ratings
Note: Stresses above those listed under “absolute maximum ratings” may cause
permanent damage to the device. Exposure to “absolute maximum rating”
conditions for extended periods may affect device reliability
Table 33 Absolute Maximum Ratings
Parameter Symbol Limit Values Unit
Ambient temperature under bias TA-40 to 85 °C
Junction temperature under bias TJ0 to 125 °C
Storage temperature Tstg - 65 to 150 °C
Supply voltage VCC - 0.5 to 3.6 V
Input voltage
(at any signal pin with respect to ground)
VI- 0.5 to 5.5 V
Output voltage level
(at any signal pin with respect to ground)
VO- 0.5 to 5.51)
1) The maximum high output level is limited to VCC. Due to 5V I/O tolerance output signals might be pulled to 5V
level by external pull-up resistors.
V
ESD robustness2)
HBM: 1.5 kW, 100 pF
2) According to MIL-Std 883D, method 3015.7 and ESD Ass. Standard EOS/ESD-5.1-1993.
The RF Pins 20, 21, 26, 29, 32, 33, 34 and 35 are not protected against voltage stress > 300 V (versus VS or
GND). The high frequency performance prohibits the use of adequate protective structures.
VESD,HB
M
1000 V
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 243 2003-01-20
9.2 Operating Range
Parameter Symbol Limit Values Unit Remarks
Min Max
Ambient temperature TA−40 85 °C
Supply voltage VCC 3.15 3.45 V 3.3V ± 5%
Input voltage VI0 5.5 V 5V I/O
tolerance
Output voltage VO05.5V
Input low voltage VIL 00.8V
Input high voltage VIH 2.1 5.5 V
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 244 2003-01-20
9.3 Thermal Package Characteristics
Parameter Symbol Limit Values Unit Test conditions
Thermal package
resistance junction to
ambient without airflow
RJA(0,25) 25 °C/W TA=25°C
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 245 2003-01-20
9.4 DC Characteristics
Parameter Symbol Limit Value Unit Test Condition
Min Max
Input low voltage VIL 00.8V
Input high voltage VIH 2.1 5.5 V
Output low voltage1)
1) All Utopia output buffers are 8 mA.
VOL 0.4 V IOL = 4 mA, 8 mA
Output high voltage1) VOH VCC - 0.6 V IOH = - 4 mA, - 8 mA
Low-level input leakage
current
ILLI ± 1 µA VI = VIL(min) = VSS
High-level input leakage
current
IHLI3.3
IHLI5.5
± 1
± 10
µA
µA
VI = VIH(VCC) = VCC
VI = VIH(max) = 5.5 V
High-impedance state
output current
IOZ ± 1 µA
Pull up current2)
2) The current is applicable for all pins for which an type PUA has been specified in Chapter 2.2
IPUA 112µAVCC = 3.3V,
VI = VIL(min) = VSS
Pull up current3)
3) The current is applicable for all pins for which an type PUB has been specified in Chapter 2.2
IPUB 40 130 µA VCC = 3.3V,
VI = VIL(min) = VSS
Pull down current4)
4) The current is applicable for all pins for which an type PDA has been specified in Chapter 2.2
IPDA 112µAVCC = 3.3V,
VI = VIH(VCC) = VCC
Power supply current
during power-up
ICC
PwrUp
700 mA VCC = 3.3V,
inputs at VSS/VCC,
no output loads,
FCLOCK = 40 MHz
Average power supply
current 5)
5) Not tested in production.
The listed characteristics are ensured over the operating range of the integrated circuit. Typical characteristics
specify mean values expected over the production spread. If not otherwise specified, typical characteristics
apply at Ta = 25 °C and the given supply voltage.
ICC Typ. 330 mA VCC = 3.3V,
inputs at VSS/VCC,
no output loads,
FCLOCK = 25 MHz
Average Power
dissipation 5) PTyp. 1.10 W
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 246 2003-01-20
9.5 Capacitances
Note: The listed characteristics are not tested in production.
Parameter Symbol Limit Value Unit Test Condition
Min Max
Input capacitance CIN 10 pF
Output capacitance COUT 15 pF
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 247 2003-01-20
9.6 AC Characteristics
TA = -40 to 85 °C, VCC = 3.3 V ± 5%, VSS = 0 V
All inputs are driven to VIH = 2.4 V for a logical “1” and
to VIL = 0.4 V for a logical “0”
All outputs are measured at VH = 2.0 V for a logical “1”and
at VL = 0.8 V for a logical “0
The AC testing input/output waveforms are shown below.
Figure 55 Input/Output Waveforms for AC Measurements
9.6.1 Clock and Reset Interface
Figure 56 Clock and Reset Interface Timing Diagram
Table 34 Clock and Reset Interface AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1T
CLOCK: Period CLOCK
GIM T1: 25,72 40 53,97 ns
others: 25,72 40 40,69 ns
Timing Test
Points
V
TH
V
TL
Device
under
Test C
L
Test Levels
V
IH
V
IL
Drive Levels
IOWFAM
CLK52
2
3
RESET
CLOCK
1
Caritd
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 248 2003-01-20
9.6.2 Framer Interface
9.6.2.1 Framer Interface in FAM
Framer Receive Interface
Figure 57 Framer Receive Interface Timing in FAM
1A FCLOCK: Frequency CLOCK1)
GIM T1: 18,53 25 38,88 MHz
others: 24,58 25 38,88 MHz
2T
CLK52: Period CLK522) -50 ppm 19.29 +50 ppm ns
2A FCLK52: Frequency CLK52 2) -50 ppm 51.84 +50 ppm MHz
3 Pulse width RESET low 3xTCLOCK
1) The frequency should be equal or higher than RXCLK and TXCLK of the UTOPIA interface
2) Only required if the Internal Clock Recovery Circuit is used for SRTS
Table 34 Clock and Reset Interface AC Timing Characteristics (cont’d)
No. Parameter Limit Values Unit
Min Typ Max
FRCLK
FRFRS
33
FRDAT
54
FRMFB
76
2
RFCLK
1
FRITFAM
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 249 2003-01-20
Table 35 Framer Receive Interface Timing in FAM
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK 1) 30,518 ns
1A FRFCLK: Frequency RFCLK 1) 32,768 MHz
2T
FRCLK: Period FRCLK - 130
ppm
122 +130
ppm
ns
2A FFRCLK: Frequency FRCLK - 130
ppm
8,192 +130
ppm
MHz
3 Delay FRCLK falling to FRFRS 332ns
4 Setup time FRDAT before FRCLK
falling (center of bit period)
15 ns
5 Hold time FRDAT after FRCLK falling
(center of bit period)
15 ns
6 Setup time FRMFB before FRCLK
falling (center of bit period)
15 ns
7 Hold time FRMFB after FRCLK falling
(center of bit period)
15 ns
1) In case the Internal Clock Recovery Circuit is used for SRTS, the frequency deviation should be +/- 10 ppm
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 250 2003-01-20
Framer Transmit Interface
Figure 58 Framer Transmit Interface Timing in FAM
Table 36 Framer Transmit Interface Timing in FAM
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK 1)
1) In case the Internal Clock Recovery Circuit is used for SRTS, the frequency deviation should be +/- 10 ppm
30,518 ns
1A FRFCLK: Frequency RFCLK 1) 32,768 MHz
2T
FTCKO: Period FTCKO -130 ppm 122 +130
ppm
ns
2A FFTCKO: Frequency FTCKO -130 ppm 8,192 +130
ppm
MHz
3 Delay FTCKO in falling to FTFRS 332ns
Delay FTCKO out falling to FTFRS -3 32 ns
4 Delay FTCKO in falling to FTDAT 3 32 ns
Delay FTCKO out falling to FTDAT -3 32 ns
5 Delay FTCKO in falling to FTMFS 3 32 ns
Delay FTCKO out falling to FTMFS -3 32 ns
FTCKO
FTFRS
33
FTDAT
4
FTMFS
5
5
2
RFCLK
1
FTITFAM
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 251 2003-01-20
9.6.2.2 Framer Interface in GIM
Framer Receive Interface
Figure 59 Framer Receive Interface Timing in GIM
Table 37 Framer Receive Interface Timing in GIM
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK 1)
E1: 30,518 ns
T1: 40,478 ns
1A FRFCLK: Frequency RFCLK 1)
E1: 32,768 MHz
T1: 24,704 MHz
2T
FRCLK: Period FRCLK
E1: 488 ns
T1: 647 ns
2A FFRCLK: Frequency FRCLK
E1: 2,048 MHz
FRCLK
FRFRS
FRDAT
54
FRMFB
76
2
RFCLK
1
FritGIM
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 252 2003-01-20
Framer Transmit Interface
Figure 60 Framer Transmit Interface Timing in GIM
T1: 1,544 MHz
4 Setup time FRDAT before FRCLK
falling (center of bit period)
15 ns
5 Hold time FRDAT after FRCLK falling
(center of bit period)
15 ns
6 Setup time FRMFB before FRCLK
falling (center of bit period)
15 ns
7 Hold time FRMFB after FRCLK falling
(center of bit period)
15 ns
1) In case the Internal Clock Recovery Circuit is used for SRTS, the frequency deviation should be +/- 10 ppm
Table 37 Framer Receive Interface Timing in GIM (cont’d)
No. Parameter Limit Values Unit
Min Typ Max
FTCKO
FTFRS
3
FTDAT
4
FTMFS
55
2
3
RFCLK
1
FtitGIM
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 253 2003-01-20
Table 38 Framer Transmit Interface Timing in GIM
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK1)
E1: 30,518 ns
T1: 40,478 ns
1A FRFCLK: Frequency RFCLK 1)
E1: 32,768 MHz
T1: 24,704 MHz
2T
FTCKO: Period FTCKO
E1: 488 ns
T1: 647 ns
2A FFTCKO: Frequency FTCKO
E1: 2,048 MHz
T1: 1,544 MHz
3 Delay FTCKO in falling to FTFRS 332ns
Delay FTCKO out falling to FTFRS -3 32 ns
4 Delay FTCKO in falling to FTDAT 3 32 ns
Delay FTCKO out falling to FTDAT -3 32 ns
5 Delay FTCKO in falling to FTMFS 3 32 ns
Delay FTCKO out falling to FTMFS -3 32 ns
1) In case the Internal Clock Recovery Circuit is used for SRTS, the frequency deviation should be +/- 10 ppm
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 254 2003-01-20
9.6.2.3 Framer Interface in SYM Mode
Framer Interface in SYM2
Figure 61 Framer Interface Timing for SYM 2.048 MHz
Table 39 Framer Interface AC Timing Characteristics in SYM2 Mode
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK 488 ns
1A FRFCLK: Frequency RFCLK 2,048 MHz
3 Setup time FRDAT before RFCLK
falling/rising (center of bit period)
15 ns
4 Hold time FRDAT after RFCLK falling/
rising (center of bit period)
15 ns
5 Setup time FRMFBN1) before RFCLK
falling/rising
1) For usage of FRMFBN in SYM mode see Chapter 7.24
15 ns
6 Hold time FRMFBN1) after RFCLK
falling
15 ns
7 Delay RFCLK falling/rising to FTDAT 3 32 ns
RFCLK
FRDAT
43
FRMFB0
65
1
FTDAT
RFCLK
1
opmo.frri = 0
opmo.frri = 1
7
Fitsym2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 255 2003-01-20
Framer Interface in SYM8
Figure 62 Framer Interface Timing in SYM 8.192 MHz
Table 40 Framer Interface Timing in SYM8
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK 122 ns
1A FRFCLK: Frequency RFCLK -130 ppm 8,192 +130ppm MHz
3 Setup time FRDAT before RFCLK
falling/rising (center of bit period)
15 ns
4 Hold time FRDAT after RFCLK falling/
rising (center of bit period)
15 ns
5Setup time FRMFBN
1) before RFCLK
falling/rising
1) For usage of FRMFBN in SYM mode see Chapter 7.24
15 ns
6 Hold time FRMFBN1) after RFCLK
falling
15 ns
7 Delay RFCLK falling to FTDAT 3 32 ns
RFCLK
FRDAT
43
FRMFB0
65
1
FTDAT
7
Fitsym8
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 256 2003-01-20
9.6.2.4 Framer Interface in EC Mode
I
Figure 63 Framer Interface Timing in EC Mode
9.6.3 UTOPIA Interface
The AC characteristics of the UTOPIA interface fulfills the ATM Forum “UTOPIA level 2
Specification, Version 1.0" as defined for the interface running at 33 MHz.
The AC characteristics are based on the timing specification for the receiver side of a
signal.
Table 41 Framer Interface Timing in EC Mode
No. Parameter Limit Values Unit
Min Typ Max
1T
RFCLK: Period RFCLK 122 ns
1A FRFCLK: Frequency RFCLK -130 ppm 8,192 +130ppm MHz
2 Delay RFCLK rising to FTFRS0 332ns
3 Setup time FRDAT before RFCLK
falling (center of bit period)
15 ns
4 Hold time FRDAT after RFCLK falling
(center of bit period)
15 ns
5 Delay RFCLK falling to FTDAT 3 32 ns
TS0.Bit1 TS1.Bit8
RFCLK
FRFRS0
22
FRDAT
4
TS1.Bit8TS0.Bit1
3
1
FTDAT
5
TS1.Bit7
5
TS1.Bit6 TS1.Bit5
FTDAT
even ports
odd ports
Fitec
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 257 2003-01-20
The setup and the hold times are defined with regard to a positive clock edge, see
Figure 64.
Taking the actual used clock frequency into account (e.g. up to the max. frequency), the
corresponding (min. and max.) transmit side “clock to output” propagation delay
specifications can be derived. The timing references (tT5 to tT12) are according
toTable 42 to Table 45.
In the following tables, A>P (column DIR, Direction) defines a signal from the ATM layer
(transmitter, driver) to the PHY layer (receiver), A<P defines a signal from the PHY layer
(transmitter, driver) to the ATM layer (receiver).
Figure 64 Setup and hold time definition (single- and multi PHY)
Figure 65 Tri-state timing (multi-PHY, multiple devices only)
Clock
Signal
tT5, tT7 tT6, tT8
input setup to clock input hold from clock
UTOPIA1
Clock
Signal
tT11 tT12
signal going low
impedance from clock
tT9 tT10
signal going low
impedance to clock
signal going high
impedance from clock
signal going high
impedance to clock
UTOPIA2
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 258 2003-01-20
Table 42 Transmit Timing (8-Bit Data Bus, 33 MHz, Single PHY)
No. Signal Name DIR Description Limit Values Unit
Min Max
t1 TXCLK1)
1) The frequency should be equal or smaller than the coreclock CLOCK
A>P TXCLK frequency (nominal) 0 33 MHz
tT2 TXCLK duty cycle 40 60 %
tT3 TXCLK peak-to-peak jitter - 5 %
tT4 TXCLK rise/fall time - 3 ns
tT5 TXDAT[7:0],
TXPTY,
TXSOC,
TXENB
A>P Input setup to TXCLK 8 - ns
tT6 Input hold from TXCLK 1 - ns
tT7 TXCLAV A<P Input setup to TXCLK 8 - ns
tT8 Input hold from TXCLK 1 - ns
Table 43 Receive Timing (8-Bit Data Bus, 33 MHz, Single PHY)
No. Signal Name DIR Description Limit Values Unit
Min Max
t1 RXCLK1)
1) The frequency should be equal or smaller than the coreclock CLOCK
A>P RXCLK frequency (nominal) 0 33 MHz
tT2 RXCLK duty cycle 40 60 %
tT3 RXCLK peak-to-peak jitter - 5 %
tT4 RXCLK rise/fall time - 3 ns
tT5 RXENB A>P Input setup to RXCLK 8 - ns
tT6 Input hold from RXCLK 1 - ns
tT7 RXDAT[7:0],
RXPTY,
RXSOC,
RXCLAV
A<P Input setup to RXCLK 8 - ns
tT8 Input hold from RXCLK 1 - ns
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 259 2003-01-20
Table 44 Transmit Timing (8-Bit Data Bus, 33 MHz, Multi-PHY)
No. Signal Name DIR Description Limit Values Unit
Min Max
t1 TXCLK1)
1) The frequency should be equal or smaller than the coreclock CLOCK
A>P TXCLK frequency (nominal) 0 33 MHz
tT2 TXCLK duty cycle 40 60 %
tT3 TXCLK peak-to-peak jitter - 5 %
tT4 TXCLK rise/fall time - 3 ns
tT5 TXDAT[7:0],
TXPTY,
TXSOC,
TXENB,
TXADR[4:0]
A>P Input setup to TXCLK 8 - ns
tT6 Input hold from TXCLK 1 - ns
tT7 TXCLAV A<P Input setup to TXCLK 8 - ns
tT8 Input hold from TXCLK 1 - ns
tT9 Signal going low impedance
to TXCLK
8- ns
tT10 Signal going high impedance
to TXCLK
0- ns
tT11 Signal going low impedance
from TXCLK
1- ns
tT12 Signal going high impedance
from TXCLK
1- ns
Table 45 Receive Timing (8-Bit Data Bus, 33 MHz, Multi-PHY)
No. Signal Name DIR Description Limit Values Unit
Min Max
t1 RXCLK1) A>P RXCLK frequency (nominal) 0 33 MHz
tT2 RXCLK duty cycle 40 60 %
tT3 RXCLK peak-to-peak jitter - 5 %
tT4 RXCLK rise/fall time - 3 ns
tT5 RXENB,
RXADR[4:0]
A>P Input setup to RXCLK 8 - ns
tT6 Input hold from RXCLK 1 - ns
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 260 2003-01-20
9.6.4 IMA Interface
At the IMA interface the IWE8 operates in cycles of 12 system clocks. ATBTC can
become active during cycle #3, the UNCHEC can become active during cycle #9. The
Port number is always active for 6 cycles.
Figure 66 Timing of the IMA Interface
tT7 RXDAT[7:0],
RXPTY,
RXSOC,
RXCLAV
A<P Input setup to RXCLK 8 - ns
tT8 Input hold from RXCLK 1 - ns
tT9 Signal going low impedance
to RXCLK
8- ns
tT10 Signal going high impedance
to RXCLK
0- ns
tT11 Signal going low impedance
from RXCLK
1- ns
tT12 Signal going high impedance
from RXCLK
1- ns
1) The frequency should be equal or smaller than the coreclock CLOCK
Table 45 Receive Timing (8-Bit Data Bus, 33 MHz, Multi-PHY) (cont’d)
No. Signal Name DIR Description Limit Values Unit
Min Max
1
3
2
PN0..2
UNCHEC
ATBTC
CLOCK
Totii
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 261 2003-01-20
9.6.5 Clock Recovery Interface
Figure 67 Clock Recovery Interface Timing Diagram
Table 46 IMA Interface AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1 Delay master clock to ATBTC 26 ns
2 Delay master clock to UNCHEC 26 ns
3 Delay master clock to PN[0:2] 26 ns
Table 47 Clock Recovery Interface AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1 Delay SCLK rising to SSP -1 11 ns
2 Setup time SDI before SCLK rising 20 ns
3 Hold time SDI after SCLK rising 0 ns
4 Delay SCLK rising to SDOD 0 11 ns
5 Delay SCLK rising to SDOR 0 11 ns
6 Delay CLOCK to SCLK 1 16 ns
Bit31Bit0 Bit30
Bit31 Bit30Bit0
Bit1
Bit1
Bit31 Bit30Bit0Bit1
1 1
32
4
5
6
SCLK
SSP
SDI
SDOD
SDOR
CLOCK
Critd
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 262 2003-01-20
9.6.6 Microprocessor Interface
9.6.6.1 Intel Mode
Figure 68 Intel Mode Write Cycle Timing Diagram
Table 48 Intel Mode Write Cycle AC Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1 Setup time MPADR before MPCS low 0 ns
2 Setup time MPCS before MPWR low 0 ns
3 Delay MPRDY low after MPWR low 2 20 ns
4 MPDAT valid after MPWR low 2 x Tclock ns
5 Pulse width MPRDY low 2 x Tclock 23xTclock ns
6 MPRDY high to MPWR high 10 ns
7 Hold time MPDAT after MPWR high 5 ns
8 Hold time MPCS after MPWR high 5 ns
9 Hold time MPADR after MPWR high 5 ns
10 Delay MPCS low to MPRDY high 2 20 ns
11 Delay MPCS high to MPRDY high
impedance
220ns
1
10
2
3 5 6
4 7
11
8
9
MPDAT
MPADR
MPCS
MPWR
MPRDY
mwctg
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 263 2003-01-20
Figure 69 Intel Mode Read Cycle Timing Diagram
Table 49 Intel Mode Read Cycle AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1 Setup time MPADR before MPCS low 0 ns
2 Setup time MPCS before MPRD low 0 ns
3 Delay MPRDY low after MPRD low 2 20 ns
4 Pulse width MPRDY low 2 x Tclock 23xTclock ns
5 MPDAT valid before MPRDY high 10 ns
6 MPRDY high to MPRD high 10 ns
7 Delay time MPDAT after MPRD high 3 ns
8 Hold time MPCS after MPRD high 5 ns
9 Hold time MPADR after MPRD high 5 ns
10 Delay MPRD low to MPDAT low
impedance
420ns
11 Delay MPRD high to MPDAT high
impedance
520ns
12 Delay MPCS low to MPRDY high 2 20 ns
13 Delay MPCS high to MPRDY high
impedance
220ns
MPDAT
MPADR
MPCS
MPRD
MPRDY
1
12
2
3 4 6
10 7
13
8
9
5
11
mrctg
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 264 2003-01-20
9.6.6.2 Motorola Mode
Figure 70 Motorola Mode Timing Diagram
Table 50 Motorola Mode AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1 Setup time MPADR before MPCS low 0 ns
2 Hold time MPADR after MPTS high 5 ns
3 Setup time MPCS before MPTS low 0 ns
4 Hold time MPCS after MPTS high 5 ns
5 Setup time MPRW before MPTS low 10 ns
6 Hold time MPRW after MPTS high 0 ns
7Delay MPCS
low to MPTA high 5 15 ns
8Delay MPTA
low after MPTS low 2 x Tclock 23x Tclock ns
9 Pulse width MPTA low Tclock Tclock ns
10 MPTA low to MPTS high 0 ns
14
3
1 2
4
7 8
9
10 11
12 13 15
1716
5 6
MPADR
MPCS
MPTS
MPRW
MPTA
MPDAT
(READ)
MPDAT
(WRITE)
Interface Motorol
a
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 265 2003-01-20
9.6.7 RAM Interface
Figure 71 RAM Interface Timing Diagram
11 Delay MPCS high to MPTA high
impedance
515ns
12 Delay MPTS low to MPDAT low
impedance
115ns
13 MPDAT valid before MPTA high 5 ns
14 Delay time MPDAT after MPTS high 2 ns
15 Delay MPTS high to MPDAT high
impedance
217ns
16 MPDAT valid after MPTS low 2 x Tclock ns
17 Hold time MPDAT after MPTS high 5 ns
Table 50 Motorola Mode AC Timing Characteristics (cont’d)
No. Parameter Limit Values Unit
Min Typ Max
RMADC
RMCLK
RMADR
RMOE
1
RMDAT
RMWR
RMCS
Basic 12 RMCLK cycle
CLOCK
AR1 AR2 AR3 AR4 AR5 AR6 AW1 AW2 AW3 AW4 AW5
2
2 2
22
22
R
1
R
2
R
3
R
4
R
5
R
6
3 4 65
W1 W2 W3 W4 W5
7
AR1
89
ritd
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 266 2003-01-20
Table 51 RAM Interface AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1 Delay RMCLK rising to RMADR 1 11 ns
2 Delay RMCLK rising to RMADC 17ns
Delay RMCLK rising to RMOE 17ns
Delay RMCLK rising to RMWR 17ns
Delay RMCLK rising to RMCS 17ns
3 Setup time RMDAT before RMCLK
rising (all read cycles)
11 ns
4 Hold time RMDAT after RMCLK rising
(all read cycles)
0ns
5 Delay RMCLK falling to RMDAT low
impedance (write cycle W1)
08ns
6 Delay RMCLK rising to RMDAT
(write cycles W2 to W5)
612ns
7 Delay RMCLK falling to RMDAT high
impedance (write cycle W5)
08ns
8 Delay CLOCK to RMCLK 6 12 ns
9T
RMCLK: Period RMCLK TCLOCK ns
9A FRMCLK: Frequency RMCLK FCLOCK MHz
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Electrical Characteristics
Data Sheet 267 2003-01-20
9.6.8 Boundary-Scan Test Interface
Figure 72 Boundary-Scan Test Interface Timing Diagram
Table 52 Boundary-Scan Test Interface AC Timing Characteristics
No. Parameter Limit Values Unit
Min Typ Max
1T
TCK: Period TCK 160 ns
1A FTCK: Frequency TCK 6,25 MHz
2 Setup time TMS, TDI before TCK rising 10 ns
3 Hold time TMS, TDI after TCK rising 10 ns
4 Delay TCK falling to TDO valid 0 30 ns
5 Delay TCK falling to TDO high
impedance
030ns
6 Pulse width TRST low 2 x TTCK ns
3
1
2
4 5
6
TRST
TCK
TDI
TDO
Btitd
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Testmode
Data Sheet 268 2003-01-20
10 Testmode
10.1 Device Identification Register
10.2 Instruction Register
The following table shows the instruction binary codes for the 4 bit instruction register.
10.3 Boundary-Scan Register
Table 53 describes the Boundary-Scan register. The register contains 299 cells. The
cells of type “control” will disable the corresponding outputs when set. The control cells
are preset to a safe logic-1 during the TEST-LOGIC-RESET state of the TAP controller.
31 28 27 12 11 1 0
Version(3:0) Partnumber(15:0) Manufacturer-ID(10:0)
0100B0000000001000110B00001000001B1
Code Boundary-Scan Instruction Register Binary Codes
0000 = EXTEST
0001 = IDCODE
0101 = SAMPLE
0101 = INTEST
0111 = CLAMP
1111 = BYPASS
Table 53 Boundary Scan Register
Name Name Name
ftcko_4_o rxdat_2_o ftcko_0_o
ftcko_4_i rxdat_3_o ftcko_0_i
ftcko_4_c rxdat_4_o ftcko_0_c
ftcko_5_o rxdat_5_o frfrsn_0_o
ftcko_5_i rxdat_6_o frfrsn_0_c
ftcko_5_c rxdat_7_o ftdat_0_o
rtsen_n rxprt_o1) ftdat_0_c
mpcs_n rxprt_c1) ftmfs_0_o
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Testmode
Data Sheet 269 2003-01-20
mpwr_n rxenb_o ftmfs_0_c
mprd_n rxenb_i ftfrsn_0_o
mpdat_0_o rxenb_c ftfrsn_0_c
mpdat_0_i rxclk frlos_1
mpdat_c rmclk frclk_1
mpdat_1_o pmt frdat_1
mpdat_1_i rmdat_0_o frmfb_1
mpdat_2_o rmdat_0_i ftcko_1_o
mpdat_2_i rmdat_c ftcko_1_i
mpdat_3_o rmdat_1_o ftcko_1_c
mpdat_3_i rmdat_1_i frfrsn_1_o
mpdat_4_o rmdat_2_o frfrsn_1_c
mpdat_4_i rmdat_2_i ftdat_1_o
mpdat_5_o rmdat_3_o ftdat_1_c
mpdat_5_i rmdat_3_i ftmfs_1_o
mpdat_6_o rmdat_4_o ftmfs_1_c
mpdat_6_i rmdat_4_i ftfrsn_1_o
mpdat_7_o rmdat_5_o ftfrsn_1_c
mpdat_7_i rmdat_5_i frlos_2
mpdat_8_o rmdat_6_o frclk_2
mpdat_8_i rmdat_6_i frdat_2
mpdat_9_o rmdat_7_o frmfb_2
mpdat_9_i rmdat_7_i ftcko_2_o
mpdat_10_o rmdat_8_o ftcko_2_i
mpdat_10_i rmdat_8_i ftcko_2_c
mpdat_11_o sdi frfrsn_2_o
mpdat_11_i rmdat_9_o frfrsn_2_c
mpdat_12_o rmdat_9_i ftdat_2_o
mpdat_12_i rmdat_10_o ftdat_2_c
mpdat_13_o rmdat_10_i ftmfs_2_o
Table 53 Boundary Scan Register (cont’d)
Name Name Name
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Testmode
Data Sheet 270 2003-01-20
mpdat_13_i rmdat_11_o ftmfs_2_c
mpdat_14_o rmdat_11_i ftfrsn_2_o
mpdat_14_i rmdat_12_o ftfrsn_2_c
mpdat_15_o rmdat_12_i frlos_3
mpdat_15_i tbus frclk_3
rfclk rmdat_13_o frdat_3
clock rmdat_13_i frmfb_3
reset_n sdod ftcko_3_o
mprdy_o sdor ftcko_3_i
mprdy_c rmdat_14_o ftcko_3_c
pn_0 rmdat_14_i frfrsn_3_o
mpir1_n rmdat_15_o frfrsn_3_c
mpir2_n rmdat_15_i ftdat_3_o
mpadr_0 rmdat_16_o ftdat_3_c
mpadr_1 rmdat_16_i ftmfs_3_o
mpadr_2 ssp ftmfs_3_c
mpadr_3 rmdat_17_o ftfrsn_3_o
mpadr_4 rmdat_17_i ftfrsn_3_c
mpadr_5 rmdat_18_o frlos_4
mpadr_6 rmdat_18_i frclk_4
mpadr_7 rmdat_19_o frdat_4
mpadr_8 rmdat_19_i frmfb_4
mpadr_9 rmdat_20_o tscsh
mpadr_10 rmdat_20_i frfrsn_4_o
mpadr_11 sclk frfrsn_4_c
mpadr_12 rmdat_21_o ftdat_4_o
mpadr_13 rmdat_21_i ftdat_4_c
mpadr_14 rmdat_22_o ftmfs_4_o
mpadr_15 rmdat_22_i ftmfs_4_c
mpadr_16 rmdat_23_o ftfrsn_4_o
Table 53 Boundary Scan Register (cont’d)
Name Name Name
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Testmode
Data Sheet 271 2003-01-20
mpadr_17 rmdat_23_i ftfrsn_4_c
licec rmdat_24_o frlos_5
clk52 rmdat_24_i frclk_5
e1t1 rmdat_25_o frdat_5
tscen rmdat_25_i frmfb_5
txadr_0 rmdat_26_o frfrsn_5_o
txadr_1 rmdat_26_i frfrsn_5_c
txadr_2 rmdat_27_o ftdat_5_o
txadr_3 rmdat_27_i ftdat_5_c
txadr_4 rmdat_28_o ftmfs_5_o
rxadr_0 rmdat_28_i ftmfs_5_c
rxadr_1 rmdat_29_o ftfrsn_5_o
rxadr_2 rmdat_29_i ftfrsn_5_c
rxadr_3 rmdat_30_o frlos_6
rxadr_4 rmdat_30_i frclk_6
pn_1 rmdat_31_o frdat_6
pn_2 rmdat_31_i frmfb_6
txcla_i2) rmdat_32_o frfrsn_6_o
txcla_o2) rmdat_32_i frfrsn_6_c
txcla_c2) rmwr_n ftdat_6_o
txenb_o rmcs_n ftdat_6_c
txenb_i rmoe_n ftmfs_6_o
txenb_c rmadc_n ftmfs_6_c
txsoc unchec_4 ftfrsn_6_o
txdat_0 rmadr_0 ftfrsn_6_c
txdat_1 rmadr_1 frlos_7
txdat_2 rmadr_2 frclk_7
txdat_3 rmadr_3 frdat_7
txdat_4 rmadr_4 frmfb_7
txdat_5 rmadr_5 ftcko_6_o
Table 53 Boundary Scan Register (cont’d)
Name Name Name
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Testmode
Data Sheet 272 2003-01-20
txdat_6 rmadr_6 ftcko_6_i
txdat_7 rmadr_7 ftcko_6_c
txprt3) rmadr_8 ftcko_7_o
uttr_n rmadr_9 ftcko_7_i
txclk rmadr_10 ftcko_7_c
rxsoc_o rmadr_11 frfrsn_7_o
rxsoc_c rmadr_12 frfrsn_7_c
rxcla_o4) rmadr_13 ftdat_7_o
rxcla_i4) rmadr_14 ftdat_7_c
rxcla_c4) rmadr_15 ftmfs_7_o
atbtc_3 frlos_0 ftmfs_7_c
rxdat_0_o frclk_0 ftfrsn_7_o
rxdat_c frdat_0 ftfrsn_7_c
rxdat_1_o frmfb_0
1) corresponds to pin RXPTY
2) corresponds to pin TXCLAV
3) corresponds to pin TXPTY
4) corresponds to pin RXCLAV
Table 53 Boundary Scan Register (cont’d)
Name Name Name
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Package Outlines
Data Sheet 273 2003-01-20
11 Package Outlines
Figure 73 Package Outline: P-BGA-256 (Plastic Metric Quad Flat Package)
pa09116
SMD = Surface Mounted Device
S
orts o
f
P
ac
ki
ng
Package outlines for tubes, trays etc. are contained in our Data Book
“Package Information”.
Dimensions in mm
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 274 2003-01-20
12 Appendix
12.1 ATM Adaptation Layer 1
The ATM Adaptation Layer 1 (AAL1) consists of two sublayers: The Segmentation and
Reassembly Sublayer (SAR), which is responsible for sequence integrity of the
transmitted ATM cell stream and the Convergency Sublayer, responsible for blocking of
user data into 47-octet SAR boundaries.
Figure 74 gives an overview on the AAL1 frame-structure as defined in ITU-T I.363.1
[31].
Figure 74 Structure of the AAL1 SAR-PDU
ATM-SDU = SAR-PDU
SAR-SDU
CSI SC CRC Py
ATM Header
User information
User information
1 octet 46 octets
47 octets
47 octets
48 octets
1 octet
5 octets
1 bit 3 bit 3 bit 1 bit
P format
Non-P format
Pointer = octet offset of data block over 2 cells (111 1111 if not required)
CSI = Convergency Sublayer Indication
Non-P Format: CSI = 0
P format: CSI = 1 if SC = 0,2,4 or 6, P-field may be inserted
CSI = 0 if SC = 1,3,5 or 7, P-field is unused (Non-P format used)
SC = Sequence Count
CRC = Cyclic Redundancy Check
Py = Even Parity bit
SN = Sequence Number incremented by 1 modulo 8 for each SAR-SDU
SNP = Sequence Number Protection
SAR = Segmentation & Reassembly
SDU = Service Data Unit
PDU = Protocol Data Unit
P
SN SNP
PointerParity
1 bit 7 bit
SAR-Sublayer
ATM Layer
CS-Sublayer
Dummy FillAAL user info
N octets
Aal1
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 275 2003-01-20
Robust Sequence Count Algorithm
This algorithm is completely described in annex D of the ETSI B-ISDN AAL type 1
Specification [17] and ITU-T I.363.1 [31] and is shown in Figure Figure 75.
The algorithm is described by a state machine of 5 states. A change in states within the
state machine is indicated by an arrow, on which there are two distinct values
represented. The first value refers to the event that originates the state change, and the
second value refers to the action to be taken as a result of that event.
A decision in this algorithm is taken after evaluation of 2 consecutive SN. This means
that when a cell is received it must be temporarily stored, waiting for the next cell before
it is finally passed to the reassembly buffer. In the state machine, an action to be taken
(accept or discard) always refers to the stored cell.
The sequence counting of modulo 8 permits that the algorithm detects a maximum of to
6 consecutive lost cells and 1 misinserted cell, assuming that misinsertion of one cell is
at least as probable as the loss of 7 consecutive cells.
Lost cells are compensated by inserting an appropriate number of dummy cells into the
transmitted data of the channel. This is required to maintain bit count integrity. The
number of octets inserted per dummy cell is equal to the number of user information
octets in the SAR-PDU payload of each cell.
When one misinserted cell is detected, the algorithm is able to delete the misinserted
cell, because of the delay of one cell in taking a decision.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 276 2003-01-20
Figure 75 Informative and Example Algorithm State Machine (Fig. III.2/I.363.1)
T1306830-95
invalid SN/discard out of seq/discard
Start
Out of
Sync
valid SN/discard
invalid SN/discard
out of seq/discard
Sync
Out of
Seq
Invalid
invalid SN/discard
invalid SN/discard
in seq/accept
in seq/accept
in seq – 1+1/accept
in seq/insert dummy cell(s) + accept
in seq – 1/discard
out of seq/accept
invalid SN/accept
in seq – 1/discard
in seq – 1+1/accept
out of seq/discard
Initialization
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 277 2003-01-20
Fast Sequence Count Algorithm
The state machines of the robust SC algorithm and the fast SC algorithm are the same.
The only difference is that in the fast algorithm, the action to be taken always refers to
the currently received cell, while in the standard algorithm it refers to the temporarily
stored cell. Therefore the fast SC algorithm does not introduce additional one-cell delay.
In the fast SC algorithm, a misinserted cell is immediately accepted in the reassembly
buffer. Only at the arrival of the next cell, it is detected that the previous cell was
misinserted. Because the misinserted cell was already accepted, the current (in
sequence) cell will be discarded instead. Lost cells are compensated with the insertion
of dummy cells as in the standard algorithm.
Frequency and Value of the Pointer Field
The pointer field contains the binary value of the offset, measured in octets, between the
end of the pointer field and the start of the structured block, in the 93 octet payload. The
payload consists of the remaining 46 octets of this SAR-PDU payload and the 47 octets
of the next SAR-PDU payload.
The frequency of occurrence of the pointer field is according to ITU-T I.363.1 [31]. The
pointer field is used exactly once in every cycle, where a cycle is the sequence of eight
consecutive SAR-PDUs with Sequence Count values 0, 1, to 7. The pointer field is used
at the first available opportunity in a cycle to point to a start of a structured block. If a start
of a structured block is not present in a cycle, then a pointer field containing a dummy
offset value ‘127’ is used at the last opportunity in the cycle.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 278 2003-01-20
12.2 Synchronous Residual Time Stamp SRTS
This sub chapter contains a short description of the SRTS method, as defined in [12] and
[31].
The SRTS algorithm is used to measure the frequency deviation of a data stream which
is packetized in ATM cells. This frequency is coded in 4 bits and sent to the receiver. At
the receiver, the correct frequency is regenerated.
The 4 RTS bits are spread over 8 ATM cells. These 8 ATM cells contain 8 x 47 byte x 8
bit/byte = 3008 bits of data. In case of an E1 line, the data arrives with 2.048 Mbit/s, thus
after 3008 bit / 2.048 Mbit/s = 1,46875 ms a complete RTS value is received. The
frequency of generated RTS values is 681 Hz.
The RTS value is calculated in the following way:
In N = 3008 cycles of Fdata, we have Mq cycles of the reduced network clock. The
reduced network clock Fnx has to fulfil the following equation: 1 <= Fnx / Fdata < 2. This
defines the value of x in the equation: Fnx = 8 kHz X 19440 / 2^x. For a full E1 line Fdata
= 2.048 MHz, x = 6 and Fnx = 2.43 MHz. The maximum input frequency deviation of 200
ppm (E1 lines: less than 50 ppm) of the data clock translates in a deviation from Mq. At
the receiving side, the same network clock is available and the numbers N and x are
known. As a result, the nominal value Mnom of Mq is known, and only the deviation from
Mnom has to be transmitted. The number of bits to transmit the deviation (p = 4) has to
be sufficient for the maximum frequency deviation.
Figure 76 The Concept of SRTS (Fig. 5/I.363.1)
t
t
T1817630-92
yy
2p
MqMnom Mmax
fs
Mmin
tolerance
N cycles T seconds
f
nx
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 279 2003-01-20
RTS values are generated as follows:
Figure 77 Generation of Residual Time Stamp (RTS) (Fig.6/ I.363.1)
The transformation of RTS values in a clock is not specified in the SRTS specifications.
Basically (the implementation is slightly different), the ICRC calculates another RTS
value based on the transmit clock. The difference between received RTS values and
locally calculated RTS values, drives a DCO. This solution can be described as a PLL
with an unusual phase comparator.
T1817640-92
T
fs
fnfnx
RTS
1
x
Latch
P-bit
counter Ct
Counter A
divided by N
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 280 2003-01-20
12.3 Adaptive Clock Method ACM
The adaptive clock method does not require information concerning the source clock
transferred over the ATM network. The speed of the transmitter is adjusted to the filling
level of the receive buffer. If the transmit clock is too slow, the buffer filling level will
increase causing the clock recovery circuit to slow down the transmit clock. If the
transmit clock is too fast the buffer filling level will decrease. In this case the clock
recovery circuit will increase the transmit clock.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 281 2003-01-20
12.4 Channel Associated Signalling
ITU-T recommendation G.704 [24] defines Channel Associated Signalling (CAS) for
interfaces at 2048 kbit/s (E1) and 1544 kbit/s (DS1) interfaces carrying 64 kbit/s
channels. The mapping of E1 or DS1 multiframes containing CAS into ATM cells is
defined in the ATM-Forum “Circuit Emulation Services Specification” [10].
In case of E1 and DS1 circuit emulation, the user information carried via AAL1 consists
of a stream of payload substructures followed by an optional signalling substructure.
Each payload and signalling substructure corresponds to one E1 multiframe / DS1
extended superframe. The payload substructure contains the channel slots and the
optional signalling substructure contains the signalling bits associated with the channels.
The following section gives an overview on this topic.
12.4.1 E1
An E1 multiframe comprises 16 consecutive frames. These are numbered from 0 to15.
The multiframe alignement signal is 0000 and occupies digit time slots 1 to 4 of 64 kbit/
s channel time slot 16 in frame 0.
When 64 kbit/s channel time slot 16 is used for channel-associated signalling, the 64
kbit/s capacity is sub-multiplexed into lower-rate signalling channels using the
multiframe alignement signal as a reference.
Details of the bit allocation are given in Table 54
Table 54 Bit allocation of E1 time slot 16 for CAS
E1 Multiframe Bit allocation of time slot 16
Frame 0 (CasBeginFrame) 0000 xyxx
Frame 1 abcd channel 1 abcd channel 16
Frame 2 abcd channel 2 abcd channel 17
... ... ...
Frame 15 abcd channel 15 abcd channel 30
x = spare bit, to be set to 1 if not used
y = Bit used for alarm indication to the remote end. In undisturbed operation, set to 0; in alarm condition, set to 1.
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 282 2003-01-20
.
Figure 78 Example Multiframe Structure for 3x64 kbit/s E1 with CAS
12.4.2 DS1
A DS1 (T1) multiframe consists of 24 frames. They are numbered from 1 to 24. In the
multiframe there are four different signalling bits (A, B, C and D) providing four
independent 333 bit/s channels, two independent 667 bit/s channels or one 1333 bit/s
channel. The four signalling bits for each time slot are transported in the last bit of each
time slot of the frames 6, 12, 18, 24. In these frames only 7 bits are available for data
transmission (Robbed Bit Signalling). When mapping DS1 Nx64 kbit/s frames into ATM
timeslot x
AAL1 header octet
AAL structure pointer = 0
timeslot y
timeslot z
timeslot y
timeslot z
timeslot x
timeslot x
timeslot x
AAL1 header octet
timeslot y
timeslot z
ABCD timeslot x ABCD tim eslot y
ABCD timeslot z unused=0000
timeslot y
timeslot z
timeslot x
timeslot z
timeslot y
timeslot x
ATM SDU
of 1st cell
ATM SDU
of 2nd cell
2nd
multi-
fram e
1st
multi-
fram e
timeslot x
timeslot y
timeslot z
1st frame
signalling
sub-
structure
15th fram e
16th fram e
1st frame
14th fram e
2nd frame
Example Multiframe Structure for 3x64 kbps E1 with C
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Appendix
Data Sheet 283 2003-01-20
cells the CAS bits may also be transmitted in the payload section. However, only the
signalling bits of the CAS substructure are relevant.
Figure 79 Example Multiframe Structure for 1x64 kbit/s DS1 with CAS
Table 55 Allocation of CAS Bits to 24 Frame Multiframe
DS1 Multiframe Digit time slot in each
channel used for
Signalling channel
identifier
Characters Signalling 333
bit/s
667
bit/s
1333
bit/s
Frame 1 (CasBeginFrame) - Frame 5 1-8 - - - -
Frame 6 1-7 8 AAA
Frame 7 - Frame 11 1-8 - - - -
Frame 12 1-7 8 B B A
Frame 13 - Frame 17 1-8 - - - -
Frame 18 1-7 8 C A A
Frame 19 - Frame 23 1-8 - - - -
Frame 24 1-7 8 D B A
timeslot x
AAL1 header octet
AAL structure pointer = 0
ABCD ts x unused=0000
ATM SDU
2nd
multi-
fram e
1st
multi-
fram e
1st frame
signalling
timeslot x 2nd frame
timeslot x 3rd frame
timeslot x 22th frame
timeslot x 23th frame
timeslot x 24th frame
timeslot x 1st frame
timeslot x 2nd frame
timeslot x 3rd frame
timeslot x 19th frame
timeslot x 20th frame
timeslot x 21st frame
Example Multiframe Structure for 1x64 kbps DS1 with
C
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Contacts for SRTS Patent Fee
Data Sheet 284 2003-01-20
13 Contacts for SRTS Patent Fee
When using the PXB 4220 a patent fee for the SRTS clock recovery needs to be paid to
Telcordia Technologies, Inc.:
Telcordia Technologies, Inc.
331 Newman Springs Road
NVC-3Z375
Red Bank, NJ 07701-5699
Web: http://www.telcordia.com
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Glossary
Data Sheet 285 2003-01-20
14 Glossary
AAL ATM Adaptation Layer
ACM Adaptive Clock Method
ATM Asynchronous Transfer Mode
B-ISDN Broadband - Integrated Services Digital Network
CBR Constant Bit Rate
CDV Cell Delay Variation
CES Circuit Emulation Service
CLP Cell Loss Priority
CRC Cyclic Redundancy Check
CS Convergence Sublayer
CSI Convergence Sublayer Indication
DCO Digitally Controlled Oscillator
DS1 Digital Signal 1 (1.544 Mbit/s) (=T1)
EC Echo Canceller
FALC Framer And Line Interface Component
FAM FALC Mode
FIFO First In, First Out Buffer
FS/DL Frame Sync/Data Link
FSM Finite State Machine
GFC Generic Flow Control
GIM Generic Interface Mode
HEC Header Error Control
I/O Input/Output
ICRC Internal Clock Recovery Circuit
ITU International Telecommunications Union
ITU-T International Telecommunications Union - Telecommunications
Standardization Sector
IWE8 Interworking Element component for 8 channels PXB 4220
IWECORE IWE8 without ICRC
LCD Loss of Cell Delineation
LIC Line Interface Card or Line Interface Circuit
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Glossary
Data Sheet 286 2003-01-20
LOS Loss of Signal
LSB Least Significant Bit
MSB Most Significant Bit
NIC Network Interface Controller or Card
NNI Network-to-Network Interface
OAM Operation, Administration, and Maintenance
OCD Out of Cell Delineation
PDU Protocol Data Unit
PHY Physical Layer Device
PTI Payload Type Identifier
RTS Residual Time Stamp
SAR Segmentation And Reassembly
SARE Segmentation And Reassembly Element, PXB 4110
SC Sequence Count
SDT Structured Data Transfer
SN Sequence Number
SNP Sequence Number Protection
SRTS Synchronous Residual Time Stamp
SSRAM Synchronous Static RAM
SYM Synchronous Mode
TAP Test Access Port
TBD To Be Defined
UDT Unstructured Data Transfer
UNI User-to-Network Interface
UTOPIA Universal Test and Operations Physical Interface for ATM
UTOPIA
Receive
Interface
(Upstream)
Data is transferred from the PHY Layer (in this case the IWE8) to the
ATM Layer.
UTOPIA
Transmit
Interface
(Downstream)
Data is transferred from the ATM Layer to the PHY Layer (in this case
the IWE8).
VC Virtual Channel
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Glossary
Data Sheet 287 2003-01-20
VCI Virtual Channel Identifier
VP Virtual Path
VPI Virtual Path Identifier
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Bibliography
Data Sheet 288 2003-01-20
15 Bibliography
1. ANSI, American National Standard for Telecommunications. Digital Hierarchy For-
mats Specification, T1.107-1995.
2. ANSI, B-ISDN Customer Installation Interfaces: Physical Layer Specification, Draft
American National Standard for Telecommunications, T1E1.2/93 020R2.
3. ANSI, B-ISDN Network Node Interfaces and Inter-Network Interfaces: Rates and
Formats Specification, Draft American National Standard for Telecommunications
T1S1.5/94 001R1.
4. ATM Forum, DS1 Physical Layer Specification, Version 1.0, af-phy-0016, September
1994
5. ATM Forum: UTOPIA Specification Level 1, Version 2.01, af-phy-0017.000, March
1994
6. ATM Forum: UTOPIA Level 2 Specification, Version 1.0, ATM Forum Contribution af-
phy-0039.000, June 1995.
7. ATM Forum, “E1 Physical Interface Specification”, af-phy-0064.000, September, 1996
8. ATM Forum, Inverse Multiplexing for ATM (IMA Specification, Version 1.1, af-phy-
0086.001, February, 1999
9. ATM Forum, “ATM on Fractional E1/T1”, str-phy-fn64-01.00, July, 1999
10.ATM Forum, Circuit Emulation Service Interoperability Specification Version 2.0, af-
vtoa-0078.000, January, 1997.
11.ATM Forum, “User-Network Interface Specification”, Version 3.1, 1994
12.Bellcore, Generic requirement, ATM and AAL protocols, GR-1113-CORE, Issue 1,
July 1994
13.Bellcore, Asynchronous Transfer Mode (ATM) and ATM Adaptation Layer (AAL)
Protocols Generic Requirements, GR-1113-CORE, Issue 1, July 1994.
14.Bellcore, “Digital Cross-Connect System - Generic Requirements and Objectives”,
TR-NWT-000170, Issue 2, January, 1993
15.Bellcore, B-ISDN UNI and NNI Physical Layer Generic Criteria, TR-NWT-001112,
Issue 1, June 1993
16.Bellcore, Transport Systems Generic Requirements, TR-TSV-000499, Issue 4,
December 1991
17.ETSI, B-ISDN ATM Adaptation Layer (AAL) Specification Type 1, prI-ETS 300353,
December 1994
18.ETSI, Transmission and Multiplexing (TM); Generic Frame Structures for the
Transport of Various Signals (including ATM cells) at the CCITT Recommendation.
G.702 Hierarchical Rates of 2048-kbit/s, 34368-kbit/s and 139264-kbit/s; pr-
ETS 300337, February 1993
19.IEEE Std 1149.1-1990, IEEE Standard Test Access Port and Boundary-Scan
Architecture
20.Infineon, Data sheet: Frame and Line Interface Component (FALC), PEB 2254
21.Infineon, Prelininary Product Overview: Smart Integrated Digital Echo Canceller
(SIDEC), PEB 20954
IWE8, V3.4
PXB 4219E, PXB 4220E, PXB 4221E
Bibliography
Data Sheet 289 2003-01-20
22.ITU-T, Recommendation G.131, Control of talker echo, revised 1996
23.ITU-T, Recommendation G.703, Physical/Electrical Characteristics of Hierarchical
Digital Interfaces, Geneva 1991
24.ITU-T, Recommendation G.704, Synchronous Frame Structures used at 1544, 6312,
2048, 8488 and 44736 kbit/s Hierarchical Levels, 07/95
25.ITU-T, Recommendation G.775, Loss of Signal and Alarm Indication Signal Defect
Detection Criteria for Equipment Interfaces described in Recommendation G.703 and
Operating at Bit Rates described in Recommendation G.702, COM 15-R 9-E, October
1993
26.ITU-T, Recommendation G.804, “ATM Cell Mapping into Plesiochronous Digital
Hierarchy (PDH)”, February 1998
27.ITU-T, Recommendation G.823, The Control of Jitter and Wander within Digital
Networks which are based on the 2048-kbit/s Hierarchy, March 1993
28.ITU-T, Recommendation G.824, The Control of Jitter and Wander within Digital
Networks which are based on the 1544-kbit/s Hierarchy, March 1993
29.ITU-T Recommendation I.231.10, “Circuit-mode Multiple-rate Unrestricted 8 kHz
Structured Bearer Service Category”
30.ITU-T, Recommendation I.361, B-ISDN ATM Layer Specification, 11/95
31.ITU-T, Draft Recommendation I.363.1, B-ISDN ATM Adaptation Layer specification:
Type 1 AAL, 08/96
32.ITU-T Recommendation I.432 “B-ISDN user-network interface - Physical layer
specification”, March, 1993
33.ITU-T Recommendation I.432.1 “B-ISDN user-network interface - Physical layer
specification: General characteristics”, August, 1996
34.ITU-T Recommendation I.432.3 “B-ISDN user-network interface - Physical layer
specification: 1544 kbit/s and 2048 kbit/s operation”, August, 1996
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