100 MHz to 2400 MHz I/Q Modulator with Integrated Fractional-N PLL and VCO ADRF6755 Data Sheet FEATURES GENERAL DESCRIPTION I/Q modulator with integrated fractional-N PLL and VCO Gain control span: 47 dB in 1 dB steps Output frequency range: 100 MHz to 2400 MHz Output 1 dB compression: 8 dBm at LO = 1800 MHz Output IP3: 20.5 dBm at LO = 1800 MHz Noise floor: -161 dBm/Hz at LO = 1800 MHz Baseband modulation bandwidth: 600 MHz (3 dB) Output frequency resolution: 1 Hz SPI and I2C-compatible serial interfaces Power supply: 5 V/380 mA The ADRF6755 is a highly integrated quadrature modulator, frequency synthesizer, and programmable attenuator. The device covers an operating frequency range from 100 MHz to 2400 MHz for use in satellite, cellular, and broadband communications. VCC1 REGOUT VREG1 VREG2 VREG3 VREG4 VREG5 VREG6 VCC2 The ADRF6755 modulator includes a high modulus, fractional-N frequency synthesizer with integrated VCO, providing less than 1 Hz frequency resolution, and a 47 dB digitally controlled output attenuator with 1 dB steps. Control of all the on-chip registers is through a user-selected SPI interface or I2C interface. The device operates from a single power supply ranging from 4.75 V to 5.25 V. VCC4 VCC3 LOMON LOMON 3.3V REGULATOR IBB IBB CCOMP1 CCOMP2 CCOMP3 47dB GAINCONTROL RANGE 0/90 RFOUT RFDIVIDER VCO CORE VTUNE TXDIS QBB QBB RSET REFERENCE REFIN x2 DOUBLER 5-BIT DIVIDER /2 + PHASE FREQUENCY - DETECTOR REFIN N-COUNTER SDI/SDA CLK/SCL SDO CS SPI/I2C INTERFACE THIRD-ORDER FRACTIONAL INTERPOLATOR FRACTIONAL REGISTER MODULUS 225 CHARGE PUMP CURRENT SETTING CP NC NC LDET CR9[7:4] INTEGER REGISTER AGND 10465-001 ADRF6755 DGND Figure 1. Rev. B Document Feedback Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 (c)2012-2013 Analog Devices, Inc. All rights reserved. Technical Support www.analog.com ADRF6755 Data Sheet TABLE OF CONTENTS Features .............................................................................................. 1 SPI Interface ................................................................................ 27 General Description ......................................................................... 1 Program Modes .......................................................................... 29 Revision History ............................................................................... 2 Register Map ................................................................................... 31 Specifications..................................................................................... 3 Register Map Summary ............................................................. 31 Timing Characteristics ................................................................ 8 Register Bit Descriptions ........................................................... 32 Absolute Maximum Ratings .......................................................... 10 Suggested Power-Up Sequence ..................................................... 35 ESD Caution ................................................................................ 10 Initial Register Write Sequence ................................................ 35 Pin Configuration and Function Descriptions ........................... 11 Evaluation Board ............................................................................ 37 Typical Performance Characteristics ........................................... 13 General Description ................................................................... 37 Theory of Operation ...................................................................... 21 Hardware Description ............................................................... 37 Overview...................................................................................... 21 PCB Artwork............................................................................... 41 PLL Synthesizer and VCO......................................................... 21 Bill of Materials ........................................................................... 44 Quadrature Modulator .............................................................. 24 Outline Dimensions ....................................................................... 45 Attenuator .................................................................................... 25 Ordering Guide .......................................................................... 45 Voltage Regulator ....................................................................... 25 I2C Interface ................................................................................ 25 REVISION HISTORY 4/13--Rev. A to Rev. B Changes to Ordering Guide .......................................................... 45 11/12--Rev. 0 to Rev. A Changes to Figure 1 .......................................................................... 1 Changes to Input Frequency Parameter, Table 1 .......................... 6 Changes to Bit 7 Description, Table 27 and Bit 6 Description, Table 27 ............................................................................................ 34 Changed 0x00 to 0x60 in Step 13 ................................................. 35 Updated Outline Dimensions ....................................................... 45 Changes to Ordering Guide .......................................................... 45 7/12--Revision 0: Initial Version Rev. B | Page 2 of 48 Data Sheet ADRF6755 SPECIFICATIONS VCC = 5 V 5%, operating temperature range = -40C to +85C, I/Q inputs = 0.9 V p-p differential sine waves in quadrature on a 500 mV dc bias, REFIN = 80 MHz, PFD = 40 MHz, baseband frequency = 1 MHz, LOMON off, loop bandwidth (LBW) = 100 kHz, ICP = 5 mA, unless otherwise noted. Table 1. Parameter OPERATING FREQUENCY RANGE RF OUTPUT = 100 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough 1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise RF OUTPUT = 300 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise Test Conditions/Comments RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth Rev. B | Page 3 of 48 Min 100 Typ Max 2400 Unit MHz -0.2 2.0 9.0 21.0 -12 -55 -80 -70 -153 -60 -85 -90 -106 -116 -127 -131 -146 -152 0.02 dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms 0.2 0.5 9.3 23.0 -20 -50 -75 -70 -158 -60 -85 -85 -105 -113 -117 -122 -145 -150 0.04 dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms ADRF6755 Parameter RF OUTPUT = 700 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise RF OUTPUT = 900 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise RF OUTPUT = 1800 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Data Sheet Test Conditions/Comments RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Attenuator setting = 0 dB to 21 dB, carrier offset = 10 MHz Attenuator setting = 21 dB to 47 dB, carrier offset = 10 MHz Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB Rev. B | Page 4 of 48 Min Typ Max Unit 0.2 0.5 9.4 23.0 -16 -48 -70 -70 -158 -60 -60 -85 -97 -106 -112 -115 -139 -154 0.07 dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms 0.0 0.5 9.2 22.8 -15 -48 -68 -60 -158.5 -152 -171 -60 -60 -80 -94 -104 -109 -114 -139 -154 0.11 dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc/Hz dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms -0.4 0.5 8.0 20.5 -13 -45 -53 -45 dBm dB dBm dBm dB dBc dBm dBc Data Sheet Parameter Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise RF OUTPUT = 1875 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise RF OUTPUT = 2100 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs ADRF6755 Test Conditions/Comments I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Attenuator setting = 0 dB to 21 dB, carrier offset = 10 MHz Attenuator setting = 21 dB to 47 dB, carrier offset = 10 MHz Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Attenuator setting = 0 dB to 21 dB, carrier offset = 10 MHz Attenuator setting = 21 dB to 47 dB, carrier offset = 10 MHz Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Attenuator setting = 0 dB to 21 dB, carrier offset = 10 MHz Attenuator setting = 21 dB to 47 dB, carrier offset = 10 MHz Integer boundary < loop bandwidth >10 MHz offset from carrier Rev. B | Page 5 of 48 Min Typ -161 -150 -170 -58 -60 -75 -89 -99 -103 -108 -133 -152 0.17 Max Unit dBm/Hz dBc/Hz dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms -0.6 0.5 7.8 20.2 -13 -45 -52 -50 -160 -150 -170 -60 -60 -73 -89 -97 -103 -108 -133 -152 0.18 dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc/Hz dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms -1.0 0.5 7.4 19.5 -12 -44 -51 -45 -161 -149 -170 -60 -60 -67 dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc/Hz dBm/Hz dBc dBc dBc ADRF6755 Parameter Phase Noise Integrated Phase Noise RF OUTPUT = 2400 MHz Nominal Output Power Gain Flatness Output P1dB Output IP3 Output Return Loss LO Carrier Feedthrough1 2x LO Carrier Feedthrough Sideband Suppression Noise Floor Baseband Harmonics Synthesizer Spurs Phase Noise Integrated Phase Noise REFERENCE CHARACTERISTICS Input Frequency Input Sensitivity Input Capacitance Input Current CHARGE PUMP ICP Sink/Source High Value Low Value Absolute Accuracy VCO Gain SYNTHESIZER Frequency Resolution Frequency Settling Maximum Frequency Step for No Autocalibration Phase Detector Frequency Data Sheet Test Conditions/Comments 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth Min RFOUT pin VIQ = 0.9 V p-p differential Any 40 MHz Max -1.7 0.5 6.5 18.5 -11 -43 -60 -40 -160.5 -148 -170 -55 -55 -64 -85 -96 -100 -107 -132 -152 0.25 f1BB = 3.5 MHz, f2BB = 4.5 MHz, POUT = -6 dBm per tone Attenuator setting = 0 dB Attenuator setting = 0 dB to 47 dB Attenuator setting = 0 dB to 47 dB I/Q inputs = 0 V p-p differential, attenuator setting = 0 dB Attenuator setting = 0 dB to 21 dB, carrier offset = 10 MHz Attenuator setting = 21 dB to 47 dB, carrier offset = 10 MHz Integer boundary < loop bandwidth >10 MHz offset from carrier 100 Hz offset 1 kHz offset 10 kHz offset 100 kHz offset 1 MHz offset 10 MHz offset 1 kHz to 8 MHz integration bandwidth REFIN pin With reference divide-by-2 enabled With reference divide-by-2 disabled With reference doubler enabled AC-coupled Typ -88 -98 -101 -108 -134 -152 0.25 10 10 10 0.4 Unit dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms dBm dB dBm dBm dB dBc dBm dBc dBm/Hz dBc/Hz dBm/Hz dBc dBc dBc dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz rms 300 165 80 VREG 10 100 MHz MHz MHz V p-p pF A Programmable, RSET = 4.7 k 5 312.5 4.0 mA A % KVCO LO = 100 MHz to 2400 MHz 25 MHz/V Any step size, maximum frequency error = 100 Hz Frequency step with no autocalibration routine; Register CR24, Bit 0 = 1 0.17 1 10 Rev. B | Page 6 of 48 100/2RFDIV Hz ms kHz 40 MHz Data Sheet Parameter GAIN CONTROL Gain Range Step Size Relative Step Accuracy Absolute Step Accuracy 4 Output Settling Time OUTPUT DISABLE Off Isolation Turn-On Settling Time Turn-Off Settling Time MONITOR OUTPUT Nominal Output Power BASEBAND INPUTS I and Q Input Bias Level 3 dB Bandwidth LOGIC INPUTS Input High Voltage, VINH Input Low Voltage, VINL Input High Voltage, VINH Input Low Voltage, VINL Input Current, IINH/IINL Input Capacitance, CIN LOGIC OUTPUTS Output High Voltage, VOH Output Low Voltage, VOL POWER SUPPLIES Voltage Range Supply Current Power-Down Current ADRF6755 Test Conditions/Comments Min Fixed frequency, adjacent steps, all attenuation steps, LO > 300 MHz 2 Over full frequency range, adjacent steps, all attenuation steps, LO > 300 MHz 3 47 dB attenuation step, LO > 300 MHz 5 Any step; output power settled to 0.2 dB TXDIS pin RFOUT, attenuator setting = 0 dB to 47 dB, TXDIS high LO, attenuator setting = 0 dB to 47 dB, TXDIS high 2x LO, attenuator setting = 0 dB to 47 dB, TXDIS high TXDIS high to low: output power to 90% of envelope Frequency settling to 100 Hz TXDIS low to high (to -55 dBm) LOMON, LOMON pins Typ Max Unit 47 1 0.3 dB dB dB 1.5 dB -2.0 15 dB s -100 -75 -50 180 20 350 dBm dBm dBm ns s ns -24 dBm 500 600 mV MHz IBB, IBB, QBB, QBB pins CS, TXDIS pins CS, TXDIS pins SDI/SDA, CLK/SCL pins SDI/SDA, CLK/SCL pins CS, TXDIS, SDI/SDA, CLK/SCL pins CS, TXDIS, SDI/SDA, CLK/SCL pins SDO, LDET pins; IOH = 500 A SDO, LDET pins; IOL = 500 A SDA (SDI/SDA); IOL = 3 mA VCC1, VCC2, VCC3, VCC4, VREG1, VREG2, VREG3, VREG4, VREG5, VREG6, and REGOUT pins; REGOUT normally connected to VREG1, VREG2, VREG3, VREG4, VREG5, and VREG6 VCC1, VCC2, VCC3, and VCC4 REGOUT, VREG1, VREG2, VREG3, VREG4, VREG5, and VREG6 VCC1, VCC2, VCC3, and VCC4 combined; REGOUT connected to VREG1, VREG2, VREG3, VREG4, VREG5, and VREG6 CR29[0] = 0, power down modulator, CR12[2] = 1, power down PLL, CR28[4] = 1, power down RFDIVIDER, CR27[2] = 0, power down LOMON Operating Temperature 1.4 1.1 1 10 V V V V A pF 0.4 0.4 V V V 0.6 2.1 2.8 4.75 5 3.3 5.25 V V 380 420 mA 7 -40 mA +85 C LO carrier feedthrough is expressed in dBc relative to the RF output power changing as the attenuator is stepped. LO carrier feedthrough is constant as the RF output is altered due to a change in the I/Q input amplitude. 2 For relative step accuracy at LO < 300 MHz, refer to Figure 37. 3 For relative step accuracy over frequency range at LO < 300 MHz, refer to Figure 39. 4 All other attenuation steps have an absolute error of <2.0 dB. 5 For absolute step accuracy at LO < 300 MHz, refer to Figure 40. 1 Rev. B | Page 7 of 48 ADRF6755 Data Sheet TIMING CHARACTERISTICS I2C Interface Timing Table 2. Parameter1 SCL Clock Frequency SCL Pulse Width High SCL Pulse Width Low Start Condition Hold Time Start Condition Setup Time Data Setup Time Data Hold Time Stop Condition Setup Time Data Valid Time Data Valid Acknowledge Time Bus Free Time Limit 400 600 1300 600 600 100 300 600 900 900 1300 Unit kHz max ns min ns min ns min ns min ns min ns min ns min ns max ns max ns min tSU;DAT tVD;DAT AND tVD;ACK (ACK SIGNAL ONLY) See Figure 2. tBUF SDA tSU;STA tHD;STA tSU;STO tLOW SCL S START CONDITION 1/ fSCL tHD;DAT S tHIGH P STOP CONDITION Figure 2. I2C Port Timing Diagram Rev. B | Page 8 of 48 S 10465-002 1 Symbol fSCL tHIGH tLOW tHD;STA tSU;STA tSU;DAT tHD;DAT tSU;STO tVD;DAT tVD;ACK tBUF Data Sheet ADRF6755 SPI Interface Timing Table 3. Parameter1 CLK Frequency CLK Pulse Width High CLK Pulse Width Low Start Condition Hold Time Data Setup Time Data Hold Time Stop Condition Setup Time SDO Access Time CS to SDO High Impedance Limit 20 15 15 5 10 5 5 15 25 Unit MHz max ns min ns min ns min ns min ns min ns min ns min ns max See Figure 3. t3 CS t1 CLK t6 t2 SDI t4 t5 SDO t7 Figure 3. SPI Port Timing Diagram Rev. B | Page 9 of 48 t8 10465-003 1 Symbol fCLK t1 t2 t3 t4 t5 t6 t7 t8 ADRF6755 Data Sheet ABSOLUTE MAXIMUM RATINGS Table 4. Parameter VCC1, VCC2, VCC3, and VCC4 Supply Voltage VREG1, VREG2, VREG3, VREG4, VREG5, and VREG6 Supply Voltage IBB, IBB, QBB, and QBB Digital I/O Analog I/O (Other Than IBB, IBB, QBB, and QBB) Maximum Junction Temperature Storage Temperature Range Rating -0.3 V to +6 V -0.3 V to +4 V 0 V to 2.5 V -0.3 V to +4 V -0.3 V to +4 V Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. ESD CAUTION 125C -65C to +150C Rev. B | Page 10 of 48 Data Sheet ADRF6755 56 55 54 53 52 51 50 49 48 47 46 45 44 43 VCC2 VCC2 AGND AGND AGND AGND AGND AGND RFOUT AGND AGND TXDIS LDET MUXOUT PIN CONFIGURATION AND FUNCTION DESCRIPTIONS 1 2 3 4 5 6 7 8 9 10 11 12 13 14 PIN 1 INDICATOR ADRF6755 TOP VIEW (Not to Scale) 42 41 40 39 38 37 36 35 34 33 32 31 30 29 VCC3 VCC3 AGND AGND VTUNE AGND VREG6 CCOMP3 CCOMP2 CCOMP1 DGND VREG5 CLK/SCL SDI/SDA NOTES 1. NC = NO CONNECT. DO NOT CONNECT TO THIS PIN. 2. CONNECT EXPOSED PAD TO GROUND PLANE VIA A LOW IMPEDANCE PATH. 10465-004 VREG3 VREG4 REFIN REFIN AGND AGND AGND AGND AGND AGND LOMON LOMON CS SDO 15 16 17 18 19 20 21 22 23 24 25 26 27 28 VCC4 IBB IBB QBB QBB AGND RSET NC CP NC VCC1 REGOUT VREG1 VREG2 Figure 4. Pin Configuration Table 5. Pin Function Descriptions Pin No. 11, 55, 56, 41, 42, 1 Mnemonic VCC1 to VCC4 12 13, 14, 15, 16, 31, 36 6, 19, 20, 21, 22, 23, 24, 37, 39, 40, 46, 47, 49, 50, 51, 52, 53, 54 32 2, 3 REGOUT VREG1 to VREG6 AGND 4, 5 QBB, QBB 33, 34, 35 38 CCOMP1 to CCOMP3 VTUNE 7 RSET 9 CP 27 CS DGND IBB, IBB Description Positive Power Supplies for I/Q Modulator. Apply a 5 V power supply to VCC1, which should be decoupled with power supply decoupling capacitors. Connect VCC2, VCC3, and VCC4 to the same 5 V power supply. 3.3 V Output Supply. Drives VREG1, VREG2, VREG3, VREG4, VREG5, and VREG6. Positive Power Supplies for PLL Synthesizer, VCO, and Serial Port. Connect these pins to REGOUT (3.3 V) and decouple them separately. Analog Ground. Connect to a low impedance ground plane. Digital Ground. Connect to the same low impedance ground plane as the AGND pins. Differential In-Phase Baseband Inputs. These high impedance inputs must be dc biased to approximately 500 mV dc and should be driven from a low impedance source. Nominal characterized ac signal swing is 450 mV p-p on each pin. These inputs are not self-biased and must be externally biased. Differential Quadrature Baseband Inputs. These high impedance inputs must be dc-biased to approximately 500 mV dc and should be driven from a low impedance source. Nominal characterized ac signal swing is 450 mV p-p on each pin. These inputs are not self-biased and must be externally biased. Internal Compensation Nodes. These pins must be decoupled to ground with a 100 nF capacitor. Control Input to the VCO. This voltage determines the output frequency and is derived from filtering the CP output voltage. Charge Pump Current Set. Connecting a resistor between this pin and ground sets the maximum charge pump output current. The relationship between ICP and RSET is as follows: 23.5 ICPmax = RSET where RSET = 4.7 k and ICP max = 5 mA. Charge Pump Output. When enabled, this output provides ICP to the external loop filter, which, in turn, drives the internal VCO. Chip Select, CMOS Input. When CS is high, the data stored in the shift registers is loaded into one of 31 latches. In I2C mode, when CS is high, the slave address of the device is 0x60, and, when CS is low, the slave address is 0x40. Rev. B | Page 11 of 48 ADRF6755 Data Sheet Pin No. 29 Mnemonic SDI/SDA 30 CLK/SCL 28 17 18 48 45 SDO REFIN REFIN RFOUT TXDIS 25, 26 LOMON, LOMON 8, 10 44 NC LDET 43 Exposed Paddle MUXOUT EP Description Serial Data Input for SPI Port/Serial Data Input/Output for I2C Port. In SPI mode, this pin is a high impedance CMOS data input, and data is loaded in an 8-bit word. In I2C mode, this pin is a bidirectional port. Serial Clock Input for SPI/I2C Port. This serial clock is used to clock in the serial data to the registers. This input is a high impedance CMOS input. Serial Data Output for SPI Port. Register states can be read back on the SDO data output line. Reference Input. This high impedance CMOS input should be ac-coupled. Reference Input Bar. This pin should be either grounded or ac-coupled to ground. RF Output. Single-ended, 50 , internally biased RF output. This pin must be ac-coupled to the load. Output Disable. This pin can be used to disable the RF output. Connect to a high logic level to disable the output. Connect to a low logic level for normal operation. Differential Monitor Outputs. These pins provide a replica of the internal local oscillator frequency (1x LO) at four different power levels: -6 dBm, -12 dBm, -18 dBm, and -24 dBm, approximately. These open-collector outputs must be terminated with external resistors to REGOUT. These outputs can be disabled through serial port programming and should be tied to REGOUT if not used. No Connect. Do not connect to these pins. Lock Detect. This output pin indicates the state of the PLL: a high level indicates a locked condition, whereas a low level indicates a loss of lock condition. Mux Output. This pin is a test output for diagnostic use only. Do not connect to this pin. Exposed Paddle. Connect to ground plane via a low impedance path. Rev. B | Page 12 of 48 Data Sheet ADRF6755 TYPICAL PERFORMANCE CHARACTERISTICS VCC = 5 V 5%, operating temperature range = -40C to +85C, I/Q inputs = 0.9 V p-p differential sine waves in quadrature on a 500 mV dc bias, REFIN = 80 MHz, PFD = 40 MHz, baseband frequency = 1 MHz, LOMON is off, loop bandwidth (LBW) = 100 kHz, ICP = 5 mA, unless otherwise noted. A nominal condition is defined as 25C, 5.00 V, and an LO frequency of 1800 MHz. A worst-case condition is defined as having the worst-case temperature, supply voltage, and LO frequency. 2 60 OUTPUT POWER (dBm) 1 NOMINAL WORST CASE 50 OCCURRENCE (%) 0 -1 -2 40 30 20 -3 25C; 5V 85C; 4.75V 85C; 5.25V -40C; 4.75V -40C; 5.25V 10 0 -60 10465-005 -5 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) -40 -35 -30 Figure 8. Sideband Suppression Distribution at Nominal and Worst-Case Conditions -30 NOMINAL WORST CASE CARRIER FEEDTHROUGH (dBc) -35 20 OCCURRENCE (%) -45 SIDEBAND SUPPRESSION (dBc) Figure 5. Output Power vs. LO Frequency, Supply, and Temperature 25 -50 -55 10465-009 -4 15 10 5 -40 -45 -50 -55 -60 -65 -70 10465-006 OUTPUT POWER (dBm) -80 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) Figure 9. LO Carrier Feedthrough vs. LO Frequency, Attenuation, Supply, and Temperature Figure 6. Output Power Distribution at Nominal and Worst-Case Conditions 0 -20 80 +25C, 5.00V +85C, 4.75V +85C, 5.25V -40C, 4.75V -40C, 5.25V NOMINAL WORST CASE 70 60 -30 OCCURRENCE (%) -40 -50 -60 50 40 30 -70 20 -80 10 -90 LO FREQUENCY (MHz) 0 -60 -58 -56 -54 -52 -50 -48 -46 -44 -42 -40 -38 -36 -34 -32 -30 10465-108 -100 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 Figure 7. Sideband Suppression vs. LO Frequency, Supply, and Temperature LO CARRIER FEEDTHROUGH (dBc) 10465-011 SIDEBAND SUPPRESSION (dBc) -10 10465-110 -75 0 -4.2 -3.8 -3.4 -3.0 -2.6 -2.2 -1.8 -1.4 -1.0 -0.6 -0.2 0.2 0.6 1.0 Figure 10. LO Carrier Feedthrough Distribution at Nominal and Worst-Case Conditions and Attenuation Setting Rev. B | Page 13 of 48 Data Sheet -40 45 -50 40 OCCURRENCE (%) -70 -80 -90 -100 0 3.5 -5 -0.5 -10 -1.0 -15 -1.5 -20 -2.0 1 -2.5 10 DIFFERENTIAL INPUT VOLTAGE (V p-p) 7.0 7.5 8.0 8.5 9.0 24 22 20 18 16 14 10 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) Figure 15. Output IP3 vs. LO Frequency at Nominal Conditions 45 9.5 40 OCCURRENCE (%) 50 7.5 6.5 26 10.0 8.0 6.0 28 10.5 8.5 5.5 12 Figure 12. Output P1dB Compression Point at Worst-Case LO Frequency vs. Supply and Temperature 9.0 5.0 30 OUTPUT IP3 INTERCEPT POINT (dBm) 1dB 0 COMPRESSION POINT 0 4.5 Figure 14. Output P1dB Compression Point Distribution at Nominal and Worst-Case Conditions IDEAL OUTPUT POWER - OUTPUT POWER (dBm) 0.5 4.0 OUTPUT P1dB (dBm) 10465-013 5 7.0 NOMINAL WORST CASE 35 30 25 20 15 6.5 5 6.0 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 0 15 LO FREQUENCY (MHz) Figure 13. Output P1dB Compression Point vs. LO Frequency at Nominal Conditions 16 17 18 19 20 21 22 OUTPUT IP3 (dBm) Figure 16. Output IP3 Distribution at Nominal and Worst-Case Conditions Rev. B | Page 14 of 48 10465-016 10 10465-115 OUTPUT P1dB (dBm) OUTPUT POWER (dBm) 1.0 15 5 Figure 11. 2x LO Carrier Feedthrough vs. LO Frequency, Attenuation, Supply, and Temperature 10 20 10465-014 LO FREQUENCY (MHz) 25 10465-117 -120 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 30 10 ATTENUATION = 0dB ATTENUATION = 12dB ATTENUATION = 21dB ATTENUATION = 33dB ATTENUATION = 47dB -110 -25 0.1 NOMINAL WORST CASE 35 -60 10465-112 2 x LO CARRIER FEEDTHROUGH (dBm) ADRF6755 Data Sheet ADRF6755 -145 -60 -147 ATTENUATION = 21dB -149 ATTENUATION = 0dB NOISE FLOOR (dBm/Hz) LO OFF ISOLATION (dBm) -70 -80 -90 -100 -110 -151 -153 -155 -157 -159 -161 -120 10465-118 LO FREQUENCY (MHz) -165 -25 70 OCCURRENCE (%) -70 -80 -90 -100 10 ATTENUATION = 0dB (dBc/Hz) 60 50 40 30 ATTENUATION = 21dB (dBm/Hz) 20 ATTENUATION = 47dB (dBm/Hz) ATTENUATION = 47dB -110 -120 10465-119 LO FREQUENCY (MHz) 0 -180 -176 -172 -168 -164 -160 -156 -152 -148 -144 -140 NOISE FLOOR AT 10MHz OFFSET FREQUENCY (dBm/Hz) AND (dBc/Hz) 10465-167 10 ATTENUATION = 21dB -130 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 Figure 21. Noise Floor at 10 MHz Offset Frequency Distribution at Worst-Case Conditions and Different Attenuation Settings Figure 18. 2 x LO Off Isolation vs. LO Frequency, Attenuation, Supply, and Temperature -40 1.0 UPPER THIRD HARMONIC (fLO + 3 x fBB) NORMALIZED OUTPUT POWER (dB) 0.5 -60 UPPER SECOND HARMONIC (fLO + 2 x fBB) -80 -90 LOWER SECOND HARMONIC (fLO - 2 x fBB) -120 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) 0 -0.5 -1.0 -1.5 -2.0 -2.5 -3.0 -3.5 LOWER THIRD HARMONIC (fLO - 3 x fBB) 10465-120 OUTPUT POWER (dBc) 5 -4.0 1 10 100 I AND Q BASEBAND INPUT FREQUENCY (MHz) Figure 22. Normalized I and Q Input Bandwidth Figure 19. Second-Order and Third-Order Harmonic Distortion vs. LO Frequency, Supply, and Temperature Rev. B | Page 15 of 48 1000 10465-023 2 x LO OFF ISOLATION (dBm) -60 -110 0 ATTENUATION = 21dB (dBc/Hz) 90 ATTENUATION = 0dB 80 -100 -5 100 -50 -70 -10 Figure 20. Noise Floor at 0 dB Attenuation vs. Output Power at Nominal Conditions -30 -50 -15 OUTPUT POWER (dBm) Figure 17. LO Off Isolation vs. LO Frequency, Attenuation, Supply, and Temperature -40 -20 10465-022 -163 ATTENUATION = 47dB -130 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 ADRF6755 Data Sheet -10 0 -12 -10 LOWER SIDEBAND 3 x LO HARMONIC ATTENUATION = 0dB -20 ATTENUATION = 21dB AND 47dB -20 -22 -40 -60 -70 -26 -80 -28 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 -90 10465-123 -24 OUTPUT FREQUENCY (MHz) 2 x LO HARMONIC -50 0 -60 -10 -70 PHASE NOISE (dBc/Hz) RF OUTPUT (dBm) CARRIER FEEDTHROUGH SUPPRESSED SIDEBAND -50 THIRD HARMONIC -60 SECOND HARMONIC 10465-025 -160 100 10 LO LO LO LO LO FREQUENCY = 2400MHz FREQUENCY = 1200MHz FREQUENCY = 580MHz FREQUENCY = 290MHz FREQUENCY = 100MHz 1k 10k 100k 1M 10M OFFSET FREQUENCY (Hz) Figure 27. Phase Noise Performance vs. LO Frequency, Nominal Conditions 0 -60 LOWER SIDEBAND -70 -80 PHASE NOISE (dBc/Hz) -20 CARRIER FEEDTHROUGH -40 SUPPRESSED SIDEBAND THIRD HARMONIC -70 LO FREQUENCY = 2500MHz -90 -100 -110 -120 -130 -140 -80 -150 -90 1825 1835 1845 1855 1865 1875 1885 1895 1905 1915 1925 -160 100 FREQUENCY (MHz) 10465-026 RF OUTPUT (dBm) 9 -130 -90 1870 1871 1872 1873 1874 1875 1876 1877 1878 1879 1880 -60 8 -120 -150 -50 7 -110 -80 Figure 24. RF Output Spectral Plot over a 10 MHz Span 6 -100 -140 FREQUENCY (MHz) 5 -90 -70 -30 4 -80 LOWER SIDEBAND -40 -10 3 Figure 26. RF Output Spectral Plot over a Wide Span 0 -30 2 FREQUENCY (MHz) Figure 23. Output Return Loss at Different Attenuation Settings vs. Output Frequency, Supply, and Temperature -20 1 10465-160 -18 5 x LO HARMONIC 4 x LO HARMONIC -30 LO FREQUENCY = 100MHz 1k 10k 100k 1M 10M OFFSET FREQUENCY (Hz) Figure 28. Phase Noise Performance vs. LO Frequency, Supply, and Temperature Figure 25. RF Output Spectral Plot over a 100 MHz Span Rev. B | Page 16 of 48 10465-128 S22 (dB) -16 10465-027 RF OUTPUT (dBm) -14 ADRF6755 -60 -70 -70 -80 -80 -90 -100 -110 -120 -130 -110 -120 -130 -150 -150 1k 10k 100k 1M 10M Figure 29. Phase Noise Performance Distribution at Worst-Case Conditions -160 100 100k 1M 10M -50 0.30 0.25 0.20 0.15 0.10 -60 -65 -70 -75 -80 -85 0.05 LO FREQUENCY (MHz) -90 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 10465-133 0 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) Figure 30. Integrated Phase Noise over an Integration Bandwidth of 1 kHz to 8 MHz vs. LO Frequency at Nominal Conditions SPURS > 10MHz OFFSET FREQUENCY (dBc) 80 70 60 50 40 30 20 0.20 0.25 0.30 0.35 0.40 RMS JITTER (Degrees) 10465-034 10 0.15 Figure 33. Integer Boundary Spur Performance vs. LO Frequency, Supply, and Temperature -50 1875MHz 2310MHz +25C 5V MAX SPUR +85C 4.75V MAX SPUR +85C 5.25V MAX SPUR -40C 4.75V MAX SPUR -40C 5.25V MAX SPUR REFERENCE SPURS AT 80MHz OFFSET PFD SPURS AT 40MHz OFFSET -60 -70 -80 -90 -100 -110 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) Figure 34. Spurs > 10 MHz from Carrier vs. LO Frequency, Supply, and Temperature Figure 31. Integrated Phase Noise Distribution over an Integration Bandwidth of 1 kHz to 8 MHz at 1875 MHz and 2310 MHz Rev. B | Page 17 of 48 10465-132 0.35 -55 10465-166 INTEGER BOUNDARY SPURS (dBc) 0.40 0 0.10 10k Figure 32. Phase Noise Performance vs. LO Frequency, Nominal Conditions with Narrow Loop Bandwidth 0.45 90 1k OFFSET FREQUENCY (Hz) 0.50 RMS JITTER (Degrees) -100 -140 OFFSET FREQUENCY (Hz) OCCURRENCE (%) -90 -140 -160 100 900MHz PHASE NOISE (dBc/Hz) 1800MHz PHASE NOISE (dBc/Hz) 2100MHz PHASE NOISE (dBc/Hz) 10465-168 PHASE NOISE (dBc/Hz) -60 10465-129 PHASE NOISE (dBc/Hz) Data Sheet ADRF6755 Data Sheet 1G 60 NOMINAL WORST CASE 100M 50 OCCURRENCE (%) 1M 100k ACQUISITION TO 100Hz 1k 100 10 1 START OF ACQUISITION LDET TIME (s) 30 20 10 NUMBER OF PFD CYCLES TO DECLARE LDET = 4096 0.1 -50 -30 -10 10 30 50 70 90 110 130 150 170 190 210 230 250 40 0 -1.0 Figure 35. PLL Frequency Settling Time at Worst-Case LO Frequency with Lock Detect Shown -0.6 -0.4 -0.2 0 0.2 0.4 0.6 0.8 1.0 ATTENUATOR RELATIVE STEP ACCURACY (dB) Figure 38. Attenuator Relative Step Accuracy Distribution at Nominal and Worst-Case Conditions, LO > 300 MHz, All Attenuation Steps 5 14 0 NOMINAL WORST CASE 12 -5 -10 10 OCCURRENCE (%) OUTPUT POWER (dBm) -0.8 10465-136 10k 10465-134 FREQUENCY ERROR (Hz) 10M -15 -20 -25 -30 8 6 4 -35 -40 2 ATTENUATOR ABSOLUTE STEP ACCURACY (dB) 1.0 0.5 0 -0.5 -1.0 -1.5 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) Figure 39. Attenuator Relative Step Accuracy Across Full Output Frequency Range Distribution at Nominal and Worst-Case Conditions, LO > 300 MHz, All Attenuation Steps 10465-138 ATTENUATOR RELATIVE STEP ACCURACY (dB) Figure 36. Attenuator Gain vs. LO Frequency by Gain Code, All Attenuator Code Steps Figure 37. Attenuator Relative Step Accuracy over all Attenuation Steps vs. LO Frequency, Nominal Conditions 2 0 -2 -4 -6 -8 -10 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) 10465-141 LO FREQUENCY (MHz) 0 -3.25 -2.25 -1.25 -0.25 0.75 1.75 2.75 -2.75 -1.75 -0.75 0.25 1.25 2.25 3.25 ATTENUATOR RELATIVE STEP ACCURACY ACROSS FULL OUTPUT FREQUENCY RANGE (dB) 10465-131 -50 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 10465-137 -45 Figure 40. Attenuator Absolute Step Accuracy over all Attenuation Steps vs. LO Frequency, Nominal Conditions Rev. B | Page 18 of 48 Data Sheet ADRF6755 10 30 NOMINAL WORST CASE 9 8 SETTLING TIME (s) OCCURRENCE (%) 25 20 15 10 7 6 5 4 3 2 5 10465-139 ATTENUATOR ABSOLUTE STEP ACCURACY (dB) 0 5 10 15 20 25 30 35 40 45 50 STARTING ATTENUATOR STEP Figure 44. Attenuator Settling Time to 0.5 dB for Small Steps (1 dB to 6 dB) at Nominal Conditions Figure 41. Attenuator Absolute Step Accuracy Distribution at Nominal and Worst-Case Conditions, LO > 300 MHz, All Attenuation Steps GAIN FLATNEES IN ANY 40MHz (dB) 0 10465-162 1 0 -5.0 -4.6 -4.2 -3.8 -3.4 -3.0 -2.6 -2.2 -1.8 -1.4 -1.0 -0.6 -0.2 0.2 2.0 20 1.5 18 16 SETTLING TIME (s) 1.0 0.5 0 -0.5 14 12 10 8 6 -1.0 4 -1.5 10465-145 18 8 16 7 14 SETTLING TIME (s) 9 6 5 4 3 25 30 35 STARTING ATTENUATOR STEP 40 45 50 30 35 40 45 50 6 2 20 25 8 1 15 20 10 4 10 15 12 2 10465-163 SETTLING TIME (s) 20 5 10 Figure 45. Attenuator Settling Time to 0.2 dB for Large Steps (7 dB to 47 dB) at Nominal Conditions 10 0 5 STARTING ATTENUATOR STEP Figure 42. Gain Flatness in any 40 MHz for all Attenuation Steps vs. LO Frequency at Nominal Conditions 0 0 Figure 43. Attenuator Setting Time to 0.2 dB for Small Steps (1 dB to 6 dB) at Nominal Conditions Rev. B | Page 19 of 48 0 0 5 10 15 20 25 30 35 40 45 50 STARTING ATTENUATOR STEP Figure 46. Attenuator Settling Time to 0.5 dB for Large Steps (7 dB to 47 dB) at Nominal Conditions 10465-164 LO FREQUENCY (MHz) 0 10465-161 2 -2.0 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 ADRF6755 Data Sheet 100 50 NOMINAL SETTLING TIME TO 0.2dB WORST CASE SETTLING TIME TO 0.2dB NOMINAL SETTLING TIME TO 0.5dB WORST CASE SETTLING TIME TO 0.5dB 40 OCCURRENCE (%) 70 60 50 40 30 30 25 20 15 10 10 5 0 0 0.5 1.5 1.0 2.0 2.5 3.0 4.0 3.5 4.5 5.0 ATTENUATOR SETTLING TIME (s) Figure 47. Attenuator Settling Time to 0.2 dB and 0.5 dB Distribution at Nominal and Worst-Case Conditions for Typical Small Step 100 0 3 6 9 12 15 18 21 24 27 30 33 Figure 50. Attenuator Settling Time to 0.2 dB and 0.5 dB Distribution at Nominal and Worst-Case Conditions for Worst-Case Large Step (47 dB to 0 dB) 0 -10 OUTPUT POWER (dBm) 80 0 ATTENUATOR SETTLING TIME (s) NOMINAL SETTLING TIME TO 0.2dB WORST CASE SETTLING TIME TO 0.2dB NOMINAL SETTLING TIME TO 0.5dB WORST CASE SETTLING TIME TO 0.5dB 90 OCCURRENCE (%) 35 20 10465-146 OCCURRENCE (%) 80 NOMINAL SETTLING TIME TO 0.2dB WORST CASE SETTLING TIME TO 0.2dB NOMINAL SETTLING TIME TO 0.5dB WORST CASE SETTLING TIME TO 0.5dB 45 10465-149 90 70 60 50 40 30 -20 TURN-ON = 180ns -30 TURN-OFF= 350ns -40 -50 20 -60 10 0 3 9 6 15 12 18 21 24 ATTENUATOR SETTLING TIME (s) Figure 48. Attenuator Settling Time to 0.2 dB and 0.5 dB Distribution at Nominal and Worst-Case Conditions for Worst-Case Small Step (36 dB to 42 dB) 100 NOMINAL SETTLING TIME TO 0.2dB WORST CASE SETTLING TIME TO 0.2dB NOMINAL SETTLING TIME TO 0.5dB WORST CASE SETTLING TIME TO 0.5dB 90 OCCURRENCE (%) 80 70 60 50 40 30 20 0 0 3 6 9 12 15 ATTENUATOR SETTLING TIME (s) 18 21 10465-148 10 Figure 49. Attenuator Settling Time to 0.2 dB and 0.5 dB Distribution at Nominal and Worst-Case Conditions for Typical Large Step Rev. B | Page 20 of 48 -70 0 1 2 3 4 5 6 7 TXDIS SETTLING TIME (s) Figure 51. TXDIS Settling Time at Worst-Case Supply and Temperature 8 10465-144 TXDIS 10465-147 0 Data Sheet ADRF6755 OVERVIEW The ADRF6755 device can be divided into the following basic building blocks: /2 TO PFD Figure 53. Reference Input Path fPFD = fREFIN x [(1 + D)/(R x (1 + T))] (1) where: fREFIN is the reference input frequency. D is the doubler bit. R is the programmed divide ratio of the binary 5-bit programmable reference divider (1 to 32). T is the R/2 divider setting bit (CR10[6] = 0 or 1). Each of these building blocks is described in detail in the sections that follow. PLL SYNTHESIZER AND VCO Overview The phase-locked loop (PLL) consists of a fractional-N frequency synthesizer with a 25-bit fixed modulus, allowing a frequency resolution of less than 1 Hz over the entire frequency range. It also has an integrated voltage-controlled oscillator (VCO) with a fundamental output frequency ranging from 2310 MHz to 4800 MHz. An RF divider, controlled by Register CR28, Bits[2:0], extends the lower limit of the local oscillator (LO) frequency range to 100 MHz. See Table 6 for more details on Register CR28. Reference Input Section The reference input stage is shown Figure 52. SW1 and SW2 are normally closed switches. SW3 is normally open. When powerdown is initiated, SW3 is closed, and SW1 and SW2 are open. This ensures that there is no loading of the REFIN pin at power-down. POWER-DOWN CONTROL If no division is required, it is recommended that the 5-bit R-divider and the divide-by-2 be disabled by setting CR5[4] = 0. If an even numbered division is required, enable the divide-by-2 by setting CR5[4] = 1 and CR10[6] = 1 and implement the remainder of the division in the 5-bit R-divider. If an odd number division is required, set CR5[4] = 1 and implement all of the division in the 5-bit R-divider. RF Fractional-N Divider The RF fractional-N divider allows a division ratio in the PLL feedback path that can range from 23 to 4095. The relationship between the fractional-N divider and the LO frequency is described in the INT and FRAC Relationship section. INT and FRAC Relationship The integer (INT) and fractional (FRAC) values make it possible to generate output frequencies that are spaced by fractions of the phase frequency detector (PFD) frequency. See the Example-- Changing the LO Frequency section for more information. The LO frequency equation is 100k LO = fPFD x (INT + (FRAC/225))/2RFDIV TO R-DIVIDER SW2 REFIN NC 5-BIT R-DIVIDER The PFD frequency equation is PLL synthesizer and VCO Quadrature modulator Attenuator Voltage regulator I2C/SPI interface NC x2 DOUBLER BUFFER SW3 NC 10465-052 SW1 Figure 52. Reference Input Stage Reference Input Path The on-chip reference frequency doubler allows the input reference signal to be doubled. This is useful for increasing the PFD comparison frequency. Making the PFD frequency higher improves the noise performance of the system. Doubling the PFD frequency usually improves the in-band phase noise performance by up to 3 dBc/Hz. The 5-bit R-divider allows the input reference frequency (REFIN) to be divided down to produce the reference clock to the PFD. Division ratios from 1 to 32 are allowed. (2) where: LO is the local oscillator frequency. fPFD is the PFD frequency. INT is the integer component of the required division factor and is controlled by the CR6 and CR7 registers. FRAC is the fractional component of the required division factor and is controlled by the CR0 to CR3 registers. RFDIV is set in Register CR28, Bits[2:0], and controls the setting of the divider at the output of the PLL. RF N-DIVIDER FROM VCO OUTPUT DIVIDERS An additional divide-by-2 (/2) function in the reference input path allows for a greater division range. N = INT + FRAC/225 THIRD-ORDER FRACTIONAL INTERPOLATOR INT REG FRAC VALUE Figure 54. RF Fractional-N Divider Rev. B | Page 21 of 48 TO PFD N-COUNTER 10465-054 * * * * * FROM REFIN PIN 10465-053 THEORY OF OPERATION ADRF6755 Data Sheet Phase Frequency Detector (PFD) and Charge Pump 2.5 The PFD takes inputs from the R-divider and the N-counter and produces an output proportional to the phase and frequency difference between them (see Figure 55 for a simplified schematic). The PFD includes a fixed delay element that sets the width of the antibacklash pulse, ensuring that there is no dead zone in the PFD transfer function. 2.3 HI D1 Q1 2.1 VTUNE (V) 1.9 1.7 1.5 1.3 UP 1.1 U1 0.9 +IN CLR1 DELAY U3 CHARGE PUMP 0.5 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 CP LO FREQUENCY (MHz) 10465-157 0.7 Figure 56. VTUNE vs. LO Frequency U2 -IN Figure 55. PFD Simplified Schematic Lock Detect (LDET) LDET (Pin 44) signals when the PLL has achieved lock to an error frequency of less than 100 Hz. On a write to Register CR0, a new PLL acquisition cycle starts, and the LDET signal goes low. When lock has been achieved, this signal returns high. The VCO displays a variation of KVCO as VTUNE varies within the band and from band to band. Figure 57 shows how KVCO varies across the full frequency range. Figure 57 is useful when calculating the loop filter bandwidth and individual loop filter components using ADISimPLLTM. ADISimPLL is an Analog Devices, Inc., simulator that aids in PLL design, particularly with respect to the loop filter. It reports parameters such as phase noise, integrated phase noise, and acquisition time for a particular set of input conditions. ADISimPLL can be downloaded from www.analog.com/adisimpll. 40 Voltage-Controlled Oscillator (VCO) Figure 56 shows a sweep of VTUNE vs. LO frequency demonstrating the three VCOs overlapping and the multiple overlapping bands within each VCO at the LO frequency range of 100 MHz to 2400 MHz. Note that Figure 56 includes the RFDIV being incorporated to provide further divisions of the fundamental VCO frequency; thus, each VCO is used on multiple different occasions throughout the full LO frequency range. The choice of three 16-band VCOs and an RFDIV allows the wide frequency range to be covered without large VCO sensitivity (KVCO) or resultant poor phase noise and spurious performance. 30 KVCO (MHz/V) The VCO core in the ADRF6755 consists of three separate VCOs, each with 16 overlapping bands. This configuration of 48 bands allows the VCO frequency range to extend from 2310 MHz to 4800 MHz. The three VCOs are divided by a programmable divider, RFDIV, controlled by Register CR28, Bits[2:0]. This divider provides divisions of 1, 2, 4, 8, and 16 to ensure that the frequency range is extended from 144.375 MHz (2310 MHz/16) to 4800 MHz (4800 MHz/1). A divide-by-2 quadrature circuit in the path to the modulator then provides the full LO frequency range from 100 MHz to 2400 MHz. 20 10 0 100 300 500 700 900 1100 1300 1500 1700 1900 2100 2300 2500 LO FREQUENCY (MHz) 10465-158 CLR2 DOWN D2 Q2 10465-055 HI Figure 57. KVCO vs. LO Frequency Autocalibration The correct VCO and band are chosen automatically by the VCO and band select circuitry when Register CR0 is updated. This is referred to as autocalibration. The autocalibration time is set by Register CR25. Autocalibration Time = (BSCDIV x 28)/PFD where: BSCDIV = Register CR25, Bits[7:0]. PFD = PFD frequency. For a PFD frequency of 40 MHz, set BSCDIV = 100 to set an autocalibration time of 70 s. Rev. B | Page 22 of 48 (3) Data Sheet ADRF6755 Note that BSCDIV must be recalculated if the PFD frequency is changed. The recommended autocalibration setting is 70 s. During this time, the VCO VTUNE is disconnected from the output of the loop filter and is connected to an internal reference voltage. A typical frequency acquisition is shown in Figure 58. 1G Programming the Correct LO Frequency There are two steps to programming the correct LO frequency. The user must calculate the RFDIV value based on the required LO frequency and PFD frequency, and the N-divider ratio that is required in the PLL. 1. 100M FREQUENCY ERROR (Hz) 10M 1M Table 6. RFDIV Lookup Table AUTOCAL TIME (s) 100k 10k ACQUISITION TO 100Hz 1k 100 10 0 25 50 75 100 125 150 175 200 225 250 TIME (s) 10465-156 1 0.1 LO Frequency (MHz) 1155 < LO < 2400 577.5 < LO 1155 288.75 < LO 577.5 144.375 < LO 288.75 100 < LO 144.375 2. Figure 58. PLL Acquisition After autocalibration, normal PLL action resumes, and the correct frequency is acquired to within a frequency error of 100 Hz in 170 s typically. For a maximum cumulative step of 100 kHz/2RFDIV, autocalibration can be turned off by setting Register CR24, Bit 0 = 1. This enables cumulative PLL acquisitions of 100 kHz (for RFDIV = /1, 50 kHz for RFDIV = /2, and so on) to occur without the autocalibration procedure, which improves acquisition times significantly (see Figure 59). 1M RFDIVIDER Divide-by-1 Divide-by-2 Divide-by-4 Divide-by-8 Divide-by-16 CR28[2:0] = RFDIV 000 001 010 011 100 CR27[4] 1 0 0 0 0 Using the following equation, calculate the value of the N-divider: N = (2RFDIV x LO)/fPFD (4) where: N is the N-divider value. RFDIV is the setting in Register CR28, Bits[2:0]. LO is the local oscillator frequency. fPFD is the PFD frequency. This equation is a different representation of Equation 2. Example to Program the Correct LO Frequency Assume that the PFD frequency is 40 MHz and that the required LO frequency is 1875 MHz. 100k FREQUENCY ERROR (Hz) Calculate the value of RFDIV, which is used to program Register CR28, Bits[2:0] and CR27, Bit 4 from the following lookup table, Table 6. From Table 6, 2RFDIV = 1 (RFDIV = 0) 10k N = (1 x 1875 x 106)/(40 x 106) = 46.875 The N-divider value is composed of integer (INT) and fractional (FRAC) components according to the following equation: 1k ACQUISITION TO 100Hz 100 N = INT + FRAC/225 10 (5) 0 50 100 TIME (s) 150 200 10465-159 INT = 46 and FRAC = 29,360,128 1 Figure 59. PLL Acquisition Without Autocalibration for a 100 kHz Step The appropriate registers must then be programmed according to the register map. The order in which the registers are programmed is important. Writing to CR0 initiates a PLL acquisition cycle. If the programmed LO frequency requires a change in the value of CR27[4] (see Table 6), CR27 should be the last register programmed, preceded by CR0. If the programmed LO frequency does not require a change in the value of CR27[4], it is optional to omit the write to CR27 and, in that case, CR0 should be the last register programmed. Rev. B | Page 23 of 48 ADRF6755 Data Sheet Overview A basic block diagram of the ADRF6755 quadrature modulator circuit is shown in Figure 60. The VCO/RFDIVIDER generates a signal at the 2x LO frequency, which is then divided down to give a signal at the LO frequency. This signal is then split into in-phase and quadrature components to provide the LO signals that drive the mixers. differential termination is recommended at the baseband inputs, and this dominates the input impedance as seen by the input baseband signal. This ensures that the input impedance, as seen by the input circuit, remains flat across the baseband bandwidth. See Figure 62 for a typical configuration. CURRENT OUTPUT DAC (EXAMPLE: AD9779) ADRF6755 OUT1_P IBB 50 V-TO-I 50 IBB IBB LOWPASS FILTER 100 OUT1_N IBB OUT2_N RFOUT TO ATTENUATOR QUAD PHASE SPLITTER QBB 50 /2 RF DIVIDER VCO 50 LOWPASS FILTER OUT2_P 100 QBB V-TO-I Figure 62. Typical Baseband Input Configuration 10465-060 QBB QBB Figure 60. Block Diagram of the Quadrature Modulator The I and Q baseband input signals are converted to currents by the V-to-I stages, which then drive the two mixers. The outputs of these mixers combine to feed the single-ended output. This single-ended output is then fed to the attenuator and, finally, to the external RFOUT signal pin. Baseband Inputs The baseband inputs, QBB, QBB, IBB, and IBB, must be driven from a differential source. The nominal drive level of 0.9 V p-p differential (450 mV p-p on each pin) should be biased to a common-mode level of 500 mV dc. To set the dc bias level at the baseband inputs, refer to Figure 61. The average output current on each of the AD9779 outputs is 10 mA. A current of 10 mA flowing through each of the 50 resistors to ground produces the desired dc bias of 500 mV at each of the baseband inputs. ADRF6755 CURRENT OUTPUT DAC (EXAMPLE: AD9779) OUT1_P IBB IBB QBB 50 QBB 10465-061 50 OUT2_P Another consideration is that the baseband inputs actually source a current of 240 A out of each of the four inputs. This current must be taken into account when setting up the dc bias of 500 mV. In the initial example based on Figure 61, an error of 12 mV occurs due to the 240 A current flowing through the 50 resistor. Analog Devices recommends that the accuracy of the dc bias should be 500 mV 25 mV. It is also important that this 240 A current have a dc path to ground. Optimization The carrier feedthrough and the sideband suppression performance of the ADRF6755 can be improved over the specifications in Table 1 by using the following optimization techniques. Carrier feedthrough results from dc offsets that occur between the P and N inputs of each of the differential baseband inputs. Normally these inputs are set to a dc bias of approximately 500 mV. 50 OUT2_N The swing of the AD9779 output currents ranges from 0 mA to 20 mA. The ac voltage swing is 1 V p-p single-ended or 2 V p-p differential with the 50 resistors in place. The 100 differential termination resistors at the baseband inputs have the effect of limiting this swing without changing the dc bias condition of 500 mV. The low-pass filter is used to filter the DAC outputs and remove images when driving a modulator. Carrier Feedthrough Nulling 50 OUT1_N 10465-062 QUADRATURE MODULATOR Figure 61. Establishing DC Bias Level on Baseband Inputs The differential baseband inputs (QBB, QBB, IBB, and IBB) consist of the bases of PNP transistors, which present a high impedance of about 30 k in parallel with approximately 2 pF of capacitance. The impedance is approximately 30 k below 1 MHz and starts to roll off at higher frequency. A 100 However, if a dc offset is introduced between the P and N inputs of either or both I and Q inputs, the carrier feedthrough is affected in either a positive or a negative fashion. Note that the dc bias level remains at 500 mV (average P and N level). The I channel offset is often held constant while the Q channel offset is varied until a minimum carrier feedthrough level is obtained. Then, while retaining the new Q channel offset, the I channel offset is adjusted until a new minimum is reached. This is usually performed at a single frequency and, thus, is not optimized over the complete frequency range. Multiple optimizations at different Rev. B | Page 24 of 48 Data Sheet ADRF6755 the CS pin (Pin 27). Bits[4:0] of the slave address are set to all 0s. The slave address consists of the seven MSBs of an 8-bit word. The LSB of the word sets either a read or a write operation (see Figure 63). Logic 1 corresponds to a read operation, whereas Logic 0 corresponds to a write operation. frequencies must be performed to ensure optimum carrier feedthrough across the full frequency range. Sideband Suppression Nulling Sideband suppression results from relative gain and relative phase offsets between the I channel and Q channel and can be optimized through adjustments to those two parameters. Adjusting only one parameter improves the sideband suppression only to a point. For optimum sideband suppression, an iterative adjustment between phase and amplitude is required. To control the device on the bus, the following protocol must be followed. The master initiates a data transfer by establishing a start condition, defined by a high-to-low transition on SDA while SCL remains high. This indicates that an address/data stream follows. All peripherals respond to the start condition and shift the next eight bits (the 7-bit address and the R/W bit). The bits are transferred from MSB to LSB. The peripheral that recognizes the transmitted address responds by pulling the data line low during the ninth clock pulse. This is known as an acknowledge bit. All other devices then withdraw from the bus and maintain an idle condition. During the idle condition, the device monitors the SDA and SCL lines waiting for the start condition and the correct transmitted address. The R/W bit determines the direction of the data. Logic 0 on the LSB of the first byte indicates that the master writes information to the peripheral. Logic 1 on the LSB of the first byte indicates that the master reads information from the peripheral. ATTENUATOR The digital attenuator consists of six attenuation blocks: 1 dB, 2 dB, 4 dB, 8 dB, and two 16 dB blocks; each is separately controlled. Each attenuation block consists of field effect transistor (FET) switches and resistors that form either a pi-shaped or a T-shaped attenuator. By controlling the states of the FET switches through the control lines, each attenuation block can be set to the pass state (0 dB) or the attenuation state (1 dB to 47 dB). The various combinations of the six blocks provide the attenuation states from 0 dB to 47 dB in 1 dB increments. VOLTAGE REGULATOR The voltage regulator is powered from a 5 V supply that is provided by VCC1 (Pin 11) and produces a 3.3 V nominal regulated output voltage, REGOUT, on Pin 12. This pin must be connected (external to the IC) to the VREG1 through VREG6 package pins. The ADRF6755 acts as a standard slave device on the bus. The data on the SDA pin (Pin 29) is eight bits long, supporting the 7-bit addresses plus the R/W bit. The ADRF6755 has 34 subaddresses to enable the user-accessible internal registers. Therefore, it interprets the first byte as the device address and the second byte as the starting subaddress. Auto-increment mode is supported, which allows data to be read from or written to the starting subaddress and each subsequent address without manually addressing the subsequent subaddress. A data transfer is always terminated by a stop condition. The user can also access any unique subaddress register on a one-by-one basis without updating all registers. Decouple the regulator output (REGOUT) with a parallel combination of 10 pF and 220 F capacitors. The 220 F capacitor, which is recommended for best performance, decouples broadband noise, leading to better phase noise. Each VREGx pin should have the following decoupling capacitors: 100 nF multilayer ceramic with an additional 10 pF in parallel, both placed as close as possible to the device under test (DUT) power supply pins. X7R or X5R capacitors are recommended. See the Evaluation Board section for more information. Stop and start conditions can be detected at any stage of the data transfer. If these conditions are asserted out of sequence with normal read and write operations, they cause an immediate jump to the idle condition. If an invalid subaddress is issued by the user, the ADRF6755 does not issue an acknowledge and returns to the idle condition. In a no acknowledge condition, the SDA line is not pulled low on the ninth pulse. See Figure 64 and Figure 65 for sample write and read data transfers, Figure 66 for the timing protocol, and Figure 2 for a more detailed timing diagram. I2C INTERFACE The ADRF6755 supports a 2-wire, I2C-compatible serial bus that drives multiple peripherals. The serial data (SDA) and serial clock (SCL) inputs carry information between any devices that are connected to the bus. Each slave device is recognized by a unique address. The ADRF6755 has two possible 7-bit slave addresses for both read and write operations. The MSB of the 7-bit slave address is set to 1. Bit A5 of the slave address is set by R/W CTRL 1 A5 MSB = 1 SET BY PIN 27 (CS) 0 0 0 0 0 X 0 = WR 1 = RD Figure 63. Slave Address Configuration Rev. B | Page 25 of 48 10465-063 SLAVE ADDRESS[6:0] ADRF6755 Data Sheet SLAVE ADDR, LSB = 0 (WR) A(S) SUBADDR S = START BIT A(S) = ACKNOWLEDGE BY SLAVE A(S) DATA A(S) DATA A(S) P 10465-064 S P = STOP BIT Figure 64. I2C Write Data Transfer SLAVE ADDR, LSB = 0 (WR) A(S) SUBADDR S = START BIT A(S) = ACKNOWLEDGE BY SLAVE A(S) S SLAVE ADDR, LSB = 1 (RD) A(S) DATA A(M) DATA A(M) P P = STOP BIT A(M) = NO ACKNOWLEDGE BY MASTER A(M) = ACKNOWLEDGE BY MASTER 10465-065 S Figure 65. I2C Read Data Transfer START BIT SDA SLAVE ADDRESS A6 SUBADDRESS A5 A7 STOP BIT DATA A0 D7 D0 S WR SLAVE ADDR[4:0] ACK ACK SUBADDR[6:1] Figure 66. I2C Data Transfer Timing Rev. B | Page 26 of 48 ACK DATA[6:1] P 10465-066 SCL Data Sheet ADRF6755 SPI INTERFACE SPI Serial Interface Functionality The ADRF6755 also supports the SPI protocol. The part powers up in I2C mode but is not locked in this mode. To stay in I2C mode, it is recommended that the user tie the CS line to either 3.3 V or GND, thus disabling SPI mode. It is not possible to lock the I2C mode, but it is possible to select and lock the SPI mode. The SPI serial interface of the ADRF6755 consists of the CS, SDI (SDI/SDA), CLK (CLK/SCL), and SDO pins. CS is used to select the device when more than one device is connected to the serial clock and data lines. CLK is used to clock data in and out of the part. The SDI pin is used to write to the registers. The SDO pin is a dedicated output for the read mode. The part operates in slave mode and requires an externally applied serial clock to the CLK pin. The serial interface is designed to allow the part to be interfaced to systems that provide a serial clock that is synchronized to the serial data. To select and lock the SPI mode, three pulses must be sent to the CS pin, as shown in Figure 67. When the SPI protocol is locked in, it cannot be unlocked while the device is still powered up. To reset the serial interface, the part must be powered down and powered up again. Serial Interface Selection The CS pin controls selection of the I2C or SPI interface. Figure 67 shows the selection process that is required to lock the SPI mode. To communicate with the part using the SPI protocol, three pulses must be sent to the CS pin. On the third rising edge, the part selects and locks the SPI protocol. Consistent with most SPI standards, the CS pin must be held low during all SPI communication to the part and held high at all other times. A Figure 68 shows an example of a write operation to the ADRF6755. Data is clocked into the registers on the rising edge of CLK using a 24-bit write command. The first eight bits represent the write command, 0xD4; the next eight bits are the register address; and the final eight bits are the data to be written to the specific register. Figure 69 shows an example of a read operation. In this example, a shortened 16-bit write command is first used to select the appropriate register for a read operation, the first eight bits representing the write command, 0xD4, and the final eight bits representing the specific register. Then the CS line is pulsed low for a second time to retrieve data from the selected register using a 16-bit read command, the first eight bits representing the read command, 0xD5, and the final eight bits representing the contents of the register being read. Figure 3 shows the timing for both SPI read and SPI write operations. B C CS (STARTING HIGH) SPI LOCKED ON THIRD RISING EDGE A B C SPI LOCKED ON THIRD RISING EDGE Figure 67. Selecting the SPI Protocol Rev. B | Page 27 of 48 SPI FRAMING EDGE 10465-067 CS (STARTING LOW) SPI FRAMING EDGE ADRF6755 Data Sheet *** CS *** CLK SDI D7 D6 D5 START D4 D3 D2 D1 D0 D7 D6 D5 D4 WRITE COMMAND [0xD4] D3 D2 D1 *** D0 REGISTER ADDRESS CS (CONTINUED) CLK (CONTINUED) D7 D6 D5 D4 D3 D2 D1 D0 10465-068 SDI (CONTINUED) STOP DATA BYTE Figure 68. SPI Byte Write Example *** CS *** CLK SDI D7 D6 D5 START D4 D3 D2 D1 D0 D7 D6 D5 D4 WRITE COMMAND [0xD4] D3 D2 D1 D0 *** REGISTER ADDRESS CS SDI D7 D6 D5 D4 D3 D2 D1 D0 X X X X X X X X SDO X X X X X X X X D7 D6 D5 D4 D3 D2 D1 D0 START READ COMMAND [0xD5] DATA BYTE Figure 69. SPI Byte Read Example Rev. B | Page 28 of 48 STOP 10465-069 CLK Data Sheet ADRF6755 PROGRAM MODES Reference Input Path The ADRF6755 has 34 8-bit registers to allow program control of a number of functions. Either an SPI or an I2C interface can be used to program the register set. For details about the interfaces and timing, see Figure 63 to Figure 69. The registers are documented in Table 8 to Table 28. The reference input path consists of a reference frequency doubler, a 5-bit reference divider, and a divide-by-2 function (see Figure 53). The doubler is programmed through Register CR10, Bit 5. The 5-bit divider and divide-by-2 are enabled by programming Register CR5, Bit 4, and the division ratio is programmed through Register CR10, Bits[4:0]. The R/2 divider is programmed through Register CR10, Bit 6. Note that these registers are double-buffered. Several settings in the ADRF6755 are double-buffered. These settings include the FRAC value, the INT value, the 5-bit R-divider value, the reference frequency doubler, the R/2 divider, the RFDIV value, and the charge pump current setting. This means that two events must occur before the part uses a new value for any of the double-buffered settings. First, the new value is latched into the device by writing to the appropriate register. Next, a new write must be performed on Register CR0. When Register CR0 is written, a new PLL acquisition takes place. For example, updating the fractional value involves a write to Register CR3, Register CR2, Register CR1, and Register CR0. Register CR3 should be written to first, followed by Register CR2 and Register CR1, and, finally, Register CR0. The new acquisition begins after the write to Register CR0. Double buffering ensures that the bits written to do not take effect until after the write to Register CR0. 12-Bit Integer Value Register CR7 and Register CR6 program the integer value (INT) of the feedback division factor (N); see Equation 5 for details. The INT value is a 12-bit number whose MSBs are programmed through Register CR7, Bits[3:0]. The LSBs are programmed through Register CR6, Bits[7:0]. The LO frequency setting is described by Equation 2. An alternative to this equation is provided by Equation 4, which details how to set the N-divider value. Note that these registers are double buffered. 25-Bit Fractional Value Register CR3 to Register CR0 program the fractional value (FRAC) of the feedback division factor (N); see Equation 5 for details. The FRAC value is a 25-bit number whose MSB is programmed through Register CR3, Bit 0. The LSB is programmed through Register CR0, Bit 0. The LO frequency setting is described by Equation 2. An alternative to this equation is described by Equation 4, which details how to set the N-divider value. Note that these registers are double buffered. Charge Pump Current Register CR9, Bits[7:4], specify the charge pump current setting. With an RSET value of 4.7 k, the maximum charge pump current is 5 mA. The following equation applies: ICPmax = 23.5/RSET The charge pump current has 16 settings from 312.5 A to 5 mA. For the loop filter that is specified in the application solution, a charge pump current of 5 mA (Register CR9[7:4] = 0xF) gives a loop bandwidth of 100 kHz, which is the recommended loop bandwidth setting. Transmit Disable Control (TXDIS) The transmit disable control (TXDIS) is used to disable the RF output. TXDIS is normally held low. When asserted (brought high), it disables the RF output. Register CR14 is used to control which circuit blocks are powered down when TXDIS is asserted. To meet both the off isolation power specifications and the turn-on/ turn-off settling time specifications, a value of 0x80 should be loaded into Register CR14. This effectively ensures that the attenuator is always enabled when TXDIS is asserted, even if other circuitry is disabled. Power-Down/Power-Up Control Bits The four programmable power-up and power-down control bits are as follows: RFDIV Value The RFDIV value is dependent on the value of the LO frequency. The RFDIV value can be selected from the list in Table 6. Apply the selected RFDIV value to Equation 4, together with the LO frequency and PFD frequency values, to calculate the correct N-divider value. Rev. B | Page 29 of 48 Register CR12, Bit 2. Master power control bit for the PLL, including the VCO. This bit is normally set to a default value of 0 to power up the PLL. Register CR28, Bit 4. Controls the RFDIVIDER. This bit is normally set to a default value of 0 to power up the RFDIVIDER. Register CR27, Bit 2. Controls the LO monitor outputs, LOMON and LOMON. The default is 0 when the monitor outputs are powered down. Setting this bit to 1 powers up the monitor outputs to one of four options, -6 dBm, -12 dBm, -18 dBm, or -24 dBm, as controlled by Register CR27, Bits[1:0]. Register CR29, Bit 0. Controls the quadrature modulator power. The default is 0, which powers down the modulator. Write a 1 to this bit to power up the modulator. ADRF6755 Data Sheet Lock Detect (LDET) Lock detect is enabled by setting Register CR23, Bit 4, to 1. The lock detect circuit is based on monitoring the up/down pulses from the PFD. As acquisition proceeds, the width of these pulses reduces until they are less than a target width (set by CR23[2]). At this point, a count of the number of successive PFD cycles is initiated, where the width of the up/down pulses remains less that the target width. When this count reaches a target count (set by CR13[6] and CR23[3]), LDET is set. The truth table for declaring LDET is given in Table 7. Table 7. Declaring LDET LDCount1 CR13[6] 0 0 1 1 LDCount0 CR23[3] 0 1 0 1 Number of PFD Cycles to Declare LDET 2048 3072 4096 16,384 The appropriate setting to use depends on the PFD frequency as well as the desired accuracy when LDET is declared. The LDET setting does not affect the acquisition time of the PLL. It only affects the time at which LDET goes high. VCO Autocalibration The VCO uses an autocalibration technique to select the correct VCO and band, as explained in the Autocalibration section. Register CR24, Bit 0, controls whether the autocalibration is enabled. For normal operation, autocalibration must be enabled. However, if using cumulative frequency steps of 100 kHz/2RFDIV or less, autocalibration can be disabled by setting this bit to 1 and then a new acquisition is initiated by writing to Register CR0. Attenuator The attenuator can be programmed from 0 dB to 47 dB in steps of 1 dB. Control is through Register CR30, Bits[5:0]. Revision Readback The revision of the silicon die can be read back via Register CR33. Rev. B | Page 30 of 48 Data Sheet ADRF6755 REGISTER MAP REGISTER MAP SUMMARY Table 8. Register Map Summary Register Address (Hex) 0x00 0x01 0x02 0x03 0x04 0x05 0x06 0x07 0x08 0x09 0x0A 0x0B 0x0C 0x0D 0x0E 0x0F 0x10 0x11 0x12 0x13 0x14 0x15 0x16 0x17 0x18 0x19 0x1A 0x1B 0x1C 0x1D 0x1E 0x1F 0x20 0x21 Register Name CR0 CR1 CR2 CR3 CR4 CR5 CR6 CR7 CR8 CR9 CR10 CR11 CR12 CR13 CR14 CR15 CR16 CR17 CR18 CR19 CR20 CR21 CR22 CR23 CR24 CR25 CR26 CR27 CR28 CR29 CR30 CR31 CR32 CR33 Type Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read/write Read only Read only Read only Rev. B | Page 31 of 48 Description Fractional Word 4 Fractional Word 3 Fractional Word 2 Fractional Word 1 Reserved 5-bit reference dividers enable Integer Word 2 Integer Word 1 and MUXOUT control Reserved Charge pump current setting Reference frequency control Reserved PLL power-up Lock Detector Control 2 TXDIS control Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Lock Detector Control 1 Autocalibration Autocalibration Timer Reserved LO monitor output and LO selection LO selection Modulator Attenuator Reserved Reserved Revision code ADRF6755 Data Sheet REGISTER BIT DESCRIPTIONS Table 9. Register CR0 (Address 0x00), Fractional Word 4 Bit 7 6 5 4 3 2 1 0 1 Table 13. Register CR5 (Address 0x05), 5-Bit Reference Divider Enable Description Fractional Word F7 Fractional Word F6 Fractional Word F5 Fractional Word F4 Fractional Word F3 Fractional Word F2 Fractional Word F1 Fractional Word F0 (LSB) 1 Bit 7 6 5 4 Double-buffered. Loaded on a write to Register CR0. Table 10. Register CR1 (Address 0x01), Fractional Word 3 Bit 7 6 5 4 3 2 1 0 1 Description1 Fractional Word F15 Fractional Word F14 Fractional Word F13 Fractional Word F12 Fractional Word F11 Fractional Word F10 Fractional Word F9 Fractional Word F8 1 Table 11. Register CR2 (Address 0x02), Fractional Word 2 1 Description1 Fractional Word F23 Fractional Word F22 Fractional Word F21 Fractional Word F20 Fractional Word F19 Fractional Word F18 Fractional Word F17 Fractional Word F16 Bit 7 6 5 4 3 2 1 0 1 Double-buffered. Loaded on a write to Register CR0. Bit [7:4] Double-buffered. Loaded on a write to Register CR0. Bit 7 6 5 4 3 2 1 0 Description Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Set to 1 Set to 0 Fractional Word F24 (MSB)1 Description1 Integer Word N7 Integer Word N6 Integer Word N5 Integer Word N4 Integer Word N3 Integer Word N2 Integer Word N1 Integer Word N0 Table 15. Register CR7 (Address 0x07), Integer Word 1 and MUXOUT Control Table 12. Register CR3 (Address 0x03), Fractional Word 1 1 Double-buffered. Loaded on a write to Register CR0. Table 14. Register CR6 (Address 0x06), Integer Word 2 Double-buffered. Loaded on a write to Register CR0. Bit 7 6 5 4 3 2 1 0 3 2 1 0 Description Set to 0 Set to 0 Set to 0 5-bit R-divider and divide-by-2 enable1 0 = disable 5-bit R-divider and divide-by-2 (default) 1 = enable 5-bit R-divider and divide-by-2 Set to 0 Set to 0 Set to 0 Set to 0 3 2 1 0 1 Description MUXOUT control 0000 = tristate 0001 = logic high 0010 = logic low 1101 = reference clock/2 1110 = RF fractional-N divider clock/2 Integer Word N111 Integer Word N101 Integer Word N91 Integer Word N81 Double-buffered. Loaded on a write to Register CR0. Double-buffered. Loaded on a write to Register CR0. Rev. B | Page 32 of 48 Data Sheet ADRF6755 Table 18. Register CR12 (Address 0x0C), PLL Power-Up Table 16. Register CR9 (Address 0x09), Charge Pump Current Setting Bit [7:4] 3 2 1 0 1 Bit 7 6 5 4 3 2 Description Charge pump current1 0000 = 0.3125 mA (default) 0001 = 0.63 mA 0010 = 0.94 mA 0011 = 1.25 mA 0100 = 1.57 mA 0101 = 1.88 mA 0110 = 2.19 mA 0111 = 2.50 mA 1000 = 2.81 mA 1001 = 3.13 mA 1010 = 3.44 mA 1011 = 3.75 mA 1100 = 4.06 mA 1101 = 4.38 mA 1110 = 4.69 mA 1111 = 5.00 mA Set to 0 Set to 0 Set to 0 Set to 0 1 0 Table 19. Register CR13 (Address 0x0D), Lock Detector Control 2 Bit 7 6 5 4 3 2 1 0 Bit 7 Table 17. Register CR10 (Address 0x0A), Reference Frequency Control 5 [4:0] 1 Description Set to 1 LDCount1 (see Table 7) Set to 1 Set to 0 Set to 1 Set to 0 Set to 0 Set to 0 Table 20. Register CR14 (Address 0x0E), TXDIS Control Double-buffered. Loaded on a write to Register CR0. Bit 7 6 Description Set to 0 Set to 0 Set to 0 Set to 1 Set to 1 Power down PLL 0 = power up PLL (default) 1 = power down PLL Set to 0 Set to 0 Description Set to 01 R/2 divider setting1 0 = bypass R/2 divider (default) 1 = select R/2 divider Reference frequency doubler (R-doubler) enable1 0 = disable doubler (default) 1 = enable doubler 5-bit R-divider setting1 00000 = divide by 32 (default) 00001 = divide by 1 00010 = divide by 2 ... 11110 = divide by 30 11111 = divide by 31 6 5 4 3 2 1 0 Description TXDIS_LOCLK 0 = LO clock always running 1 = stop LO clock when TXDIS = 1 Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Table 21. Register CR23 (Address 0x17), Lock Detector Control 1 Bit 7 6 5 4 Double-buffered. Loaded on a write to Register CR0. 3 2 1 0 Rev. B | Page 33 of 48 Description Set to 0 Set to 1 Set to 1 Lock detector enable 0 = lock detector disabled (default) 1 = lock detector enabled Lock detector up/down count, LDCount0 (see Table 7) Lock detector precision 0 = low, coarse (10 ns) 1 = high, fine (6 ns) Set to 0 Set to 0 ADRF6755 Data Sheet Table 22. Register CR24 (Address 0x18), Autocalibration Table 26. Register CR29 (Address 0x1D), Modulator Bit 7 6 5 4 3 2 1 0 Bit 7 6 5 4 3 2 1 0 Description Set to 0 Set to 0 Set to 0 Set to 1 Set to 1 Set to 0 Set to 0 Disable autocalibration 0 = enable autocalibration (default) 1 = disable autocalibration Description Set to 1 Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Set to 0 Power up modulator 0 = power down (default) 1 = power up Table 23. Register CR25 (Address 0x19), Autocalibration Timer Table 27. Register CR30 (Address 0x1E), Attenuator Bit [7:0] Bit 7 6 [5:0] Description Autocalibration timer Table 24. Register CR27 (Address 0x1B), LO Monitor Output and LO Selection Bit 7 6 5 4 3 2 [1:0] Description Set to 0 Set to 0 Set to 0 Frequency range; set according to Table 6 Set to 0 Power up LO monitor output 0 = power down (default) 1 = power up Monitor output power into 50 00 = -24 dBm (default) 01 = -18 dBm 10 = -12 dBm 11 = -6 dBm Table 25. Register CR28 (Address 0x1C), LO Selection Bit 7 6 5 4 3 [2:0] 1 Description Set to 0 Set to 0 Attenuator A5 to Attenuator A0 000000 = 0 dB 000001 = 1 dB 000010 = 2 dB ... 011111 = 31 dB 110000 = 32 dB 110001 = 33 dB ... 111101 = 45 dB 111110 = 46 dB 111111 = 47 dB Table 28. Register CR33 (Address 0x21), Revision Code1 Bit [7:0] 1 Description Revision code Read-only register. Description Set to 0 Set to 0 Set to 0 Power down RFDIVIDER 0 = power up (default) 1 = power down Set to 1 RFDIV1, set according to Table 6 Double-buffered. Loaded on a write to Register CR0. Rev. B | Page 34 of 48 Data Sheet ADRF6755 SUGGESTED POWER-UP SEQUENCE INITIAL REGISTER WRITE SEQUENCE After applying power to the part, perform the initial register write sequence that follows. Note that Register CR33, Register CR32, and Register CR31 are read-only registers. Also, note that all writable registers should be written to on power-up. Refer to the Register Map section for more details on all registers. 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18. 19. 20. 21. Write 0x00 to Register CR30. Set the attenuator to 0 dB gain. Write 0x80 to Register CR29. The modulator is powered down. The modulator is powered down by default to ensure that no spurious signals can occur on the RF output when the PLL is carrying out its first acquisition. The modulator should be powered up only when the PLL is locked. Write 0x0X to Register CR28. RFDIV depends on the value of the LO frequency to be used and is set according to Table 6. Note that Register CR28, Bit 3, is set to 1. Write 0xX0 to Register CR27. Bit 4 depends on the LO frequency to be used and is set according to Table 6. Write 0x00 to Register CR26. Reserved register. Write 0x64 to Register CR25, the autocalibration timer. This setting applies for PFD = 40 MHz. For other PFDs, refer to Equation 3 in the VCO Autocalibration section. Write 0x18 to Register CR24. Enable autocalibration. Write 0x70 to Register CR23. Enable the lock detector and choose the recommended lock detect timing. This setting applies to PFD = 40 MHz. For other PFDs, refer to the Lock Detect (LDET) section in the Program Modes section. Write 0x80 to Register CR22. Reserved register. Write 0x00 to Register CR21. Reserved register. Write 0x00 to Register CR20. Reserved register. Write 0x80 to Register CR19. Reserved register. Write 0x60 to Register CR18. Reserved register. Write 0x00 to Register CR17. Reserved register. Write 0x00 to Register CR16. Reserved register. Write 0x00 to Register CR15. Reserved register. Write 0x80 to Register CR14. Stop LO when TXDIS = 1. Write 0xE8 to Register CR13. This setting applies to PFD = 40 MHz. For other PFDs, refer to the Lock Detect (LDET) section in the Program Modes section. Write 0x18 to Register CR12. Power up the PLL. Write 0x00 to Register CR11. Reserved register. Write to Register CR10. Refer to the Reference Input Path section, in particular Equation 1. 22. Write 0xF0 to Register CR9. With the recommended loop filter component values and RSET = 4.7 k, as shown in Figure 70, the charge pump current is set to 5 mA for a loop bandwidth of 100 kHz. 23. Write 0x00 to Register CR8. Reserved register. 24. Write 0x0X to Register CR7. Set according to Equation 2 in the Theory of Operation section. Also, set the MUXOUT pin to tristate. 25. Write 0xXX to Register CR6. Set according to Equation 2 in the Theory of Operation section. 26. Write to Register CR5. Refer to the Reference Input Path section, in particular Equation 1. 27. Write 0x01 to Register CR4. Reserved register. 28. Write 0000010X binary to Register CR3. Set according to Equation 2 in the Theory of Operation section. 29. Write 0xXX to Register CR2. Set according to Equation 2 in the Theory of Operation section. 30. Write 0xXX to Register CR1. Set according to Equation 2 in the Theory of Operation section. 31. Write 0xXX to Register CR0. Set according to Equation 2 in the Theory of Operation section. Register CR0 must be the last register written for all the double-buffered bit writes to take effect. 32. Write to Register CR27, setting Bit 4 according to Table 6. 33. Monitor the LDET output or wait 170 s to ensure that the PLL is locked. 34. Write 0x81 to Register CR29. Power up the modulator. The write to Register CR29 does not need to be followed by a write to Register CR0 because this register is not double-buffered. Example--Changing the LO Frequency Following is an example of how to change the LO frequency after the initialization sequence. Using an example in which the PLL is locked to 2000 MHz, the following conditions apply: * * * fPFD = 40 MHz (assumed) Divide ratio N = 50; therefore, INT = 50 decimal and FRAC = 0 RFDIVIDER = divide-by-1. See Table 6. Register CR28[2:0] = 000 Register CR27[4] = 1 The INT registers contain the following values: Register CR7 = 0x00 and Register CR6 = 0x32 The FRAC registers contain the following values: Register CR3 = 0x04, Register CR2 = 0x00, Register CR1 = 0x00, and Register CR0 = 0x00 Rev. B | Page 35 of 48 ADRF6755 Data Sheet To change the LO frequency to 925 MHz, * * * fPFD = 40 MHz (assumed) Divide ratio N = 46.25; therefore, INT = 46 decimal and FRAC = 8,388,608 RFDIVIDER = divide-by-2. See Table 6. Register CR28[2:0] = 001 Register CR27[4] = 0 The FRAC registers contain the following values: Register CR3 = 0x04, Register CR2 = 0x80, Register CR1 = 0x00, and Register CR0 = 0x00 Note that Register CR27 should be the last write in this sequence, preceded by CR0. Writing to Register CR0 causes all double-buffered registers to be updated, including the INT, FRAC, and RFDIV registers, and starts a new PLL acquisition. The INT registers contain the following values: Register CR7 = 0x00 and Register CR6 = 0x2E Rev. B | Page 36 of 48 Data Sheet ADRF6755 EVALUATION BOARD GENERAL DESCRIPTION SPI Interface The EVAL-ADRF6755SDZ evaluation board is designed to allow the user to evaluate the performance of the ADRF6755. It contains the following: The SPI interface is provided by an additional SPD-S board. This must be ordered with the ADRF6755 evaluation board. The system demonstration platform (SDP) is a hardware and software platform that provides a means to communicate from the PC to Analog Devices products and systems that require digital control and/or readback (see Figure 71). * * * * * * * I/Q modulator with integrated fractional-N PLL and VCO Connector to interface to a standard USB interface board (SPD-S) that must be ordered with the EVAL-ADRF6755SDZ board. DC biasing and filter circuitry for the baseband inputs Low-pass loop filter circuitry An 80 MHz reference clock Circuitry to monitor the LOMON outputs SMA connectors for power supplies and the RF output The SDP-S controller board connects to the PC via USB 2.0 and to the ADRF6755 evaluation board via a small footprint, 120-pin connector. The SDP-S (serial only interface) is a low cost, small form factor, SDP controller board. Baseband Inputs For more information, refer to the circuit diagram in Figure 70. The pair of I and Q baseband inputs are served by SMA inputs (J2 to J5) so that they can be driven directly from an external generator or a DAC board, both of which can also provide the dc bias required. There is also an option to filter the baseband inputs, although filtering may not be required, depending on the quality of the baseband source. Power Supplies Loop Filter An external 5 V supply, DUT +5 V (J14), drives both an on-chip 3.3 V regulator and the quadrature modulator. A fourth-order loop filter is provided at the output of the charge pump and is required to adequately filter noise from the - modulator used in the N-divider. With the charge pump current set to a value of 5 mA and using the on-chip VCO, the loop bandwidth is approximately 100 kHz, and the phase margin is 55. C0G capacitors are recommended for use in the loop filter because they have low dielectric absorption, which is required for fast and accurate settling time. The use of non-C0G capacitors may result in a long tail being introduced into the settling time transient. The evaluation board is supplied with the associated driver software to allow easy programming of the ADRF6755. HARDWARE DESCRIPTION The regulator feeds the VREG1 through VREG6 pins on the chip with 3.3 V. These pins power the PLL circuitry. The external reference clock generator should be driven by a 3.3 V supply. This supply should be connected via an SMA connector, OSC +V (J15). Recommended Decoupling for Supplies The external DUT +5 V supply is decoupled initially by a 10 F capacitor and then further by a parallel combination of 100 nF and 10 pF capacitors that are placed as close to the DUT as possible for good local decoupling. The regulator output should be decoupled by a parallel combination of 10 pF and 220 F capacitors. The 220 F capacitor decouples broadband noise, which leads to better phase noise and is recommended for best performance. Case Size C 220 F capacitors are used to minimize area. Place a parallel combination of 100 nF and 10 pF capacitors on each VREGx pin, as close to the pins as possible. The impedance of these capacitors should be low and constant across a broad frequency range. Surface-mount multilayered ceramic chip (MLCC) Class II capacitors provide very low ESL and ESR, which assist in decoupling supply noise effectively. They also provide good temperature stability and good aging characteristics. Capacitance also changes vs. applied bias voltage. Larger case sizes have less capacitance change vs. applied bias voltage and have lower ESR but higher ESL. The 0603 size capacitors provide a good compromise. X5R and X7R capacitors are examples of these types of capacitors and are recommended for decoupling. Reference Input The reference input can be supplied by an 80 MHz Jauch clock generator or by an external clock through the use of Connector REFIN (J7). The frequency range of the PFD input is from 10 MHz to 40 MHz; if the 80 MHz clock generator is used, the on-chip 5-bit reference frequency divider or the divide-by-2 divider should be used to set the PFD frequency to 40 MHz to optimize phase noise performance. LOMON Outputs These pins are differential LO monitor outputs that provide a replica of the internal LO frequency at 1x LO. The single-ended power in a 50 load can be programmed to -24 dBm, -18 dBm, -12 dBm, or -6 dBm. These open-collector outputs must be terminated to 3.3 V. Because both outputs must be terminated to 50 , options are provided to terminate to 3.3 V using onboard 50 resistors or by series inductors (or a ferrite bead), in which case the 50 termination is provided by the measuring instrument. If not used, these outputs should be tied to REGOUT. Rev. B | Page 37 of 48 ADRF6755 Data Sheet CCOMPx Pins Lock Detect (LDET) The CCOMPx pins are internal compensation nodes that must be decoupled to ground with a 100 nF capacitor. Lock detect is a CMOS output that indicates the state of the PLL. A high level indicates a locked condition, and a low level indicates a loss of lock condition. MUXOUT MUXOUT is a test output that allows different internal nodes to be monitored. It is a CMOS output stage that requires no termination. TXDIS This input disables the RF output. It can be driven from an external stimulus or simply connected high or low by Jumper J18. RF Output (RFOUT) RFOUT (J12) is the RF output of the ADRF6755. Rev. B | Page 38 of 48 Data Sheet ADRF6755 10465-071 Figure 70. Applications Circuit Schematic Rev. B | Page 39 of 48 Data Sheet 10465-078 ADRF6755 Figure 71. Applications Circuit Schematic--SDP-S Rev. B | Page 40 of 48 Data Sheet ADRF6755 PCB ARTWORK 10465-072 Component Placement 10465-073 Figure 72. Evaluation Board, Top Side Component Placement Figure 73. Evaluation Board, Bottom Side Component Placement Rev. B | Page 41 of 48 ADRF6755 Data Sheet 10465-074 PCB Layer Information 10465-075 Figure 74. Evaluation Board, Top Side--Layer 1 Figure 75. Evaluation Board, Bottom Side--Layer 4 Rev. B | Page 42 of 48 ADRF6755 10465-076 Data Sheet 10465-077 Figure 76. Evaluation Board, Ground--Layer 2 Figure 77. Evaluation Board Power--Layer 3 Rev. B | Page 43 of 48 ADRF6755 Data Sheet BILL OF MATERIALS Table 29. Bill of Materials Qty 1 1 1 2 12 Description ADRF6755, 56-lead 8 mm x 8 mm LFCSP Crystal Oscillator, 80 MHz Connector, FX8-120S-SV(21) Capacitor, 10 F, 25 V, tantalum, TAJ-C Capacitor, 10 pF, 50 V, ceramic, C0G, 0402 Manufacturer Analog Devices Jauch Hirose AVX Murata Part Number ADRF6755ACPZ O 80.0-JO75-B-3.3-2-T1 FEC 1324660 FEC 197518 FEC 8819564 Capacitor, 100 nF, 25 V, X7R, ceramic, 0603 AVX FEC 317287 1 4 1 1 2 2 3 11 2 Reference Designator DUT Y2 CONN1 C1, C21 C4, C6, C8, C10, C12, C14, C16, C18, C19, C48, C53, C55 C5, C7, C9, C11, C13, C15, C17, C22, C47, C49 to C52, C54 C20 C30 to C33 C26 C24 C23, C25 C38, C39 C44, C46, C57 J2 to J5, J7, J10 to J12, J14, J15, TXDIS J18, J21 Capacitor, 220 F, 6.3 V, tantalum, Case Size C Capacitor spacing, 0402 (do not install) Capacitor, 1.2 nF, 50 V, C0G, ceramic, 0603 Capacitor, 47 nF, 50 V, C0G, ceramic, 1206 Capacitor, 560 pF, 50 V, NP0, ceramic, 0603 Capacitor, 1 nF, 50 V, C0G, ceramic, 0402 Capacitor, 100 pF, 50 V, C0G, ceramic, 0402 SMA end launch connector Jumper, 3-pin + shunt AVX FEC 197087 Kemet Murata Murata Murata Murata Johnson/Emerson Harwin 2 2 5 2 1 2 1 2 3 4 3 2 1 1 L1, L2 L3, L4 R6 to R9, R36 R10, R11 R13 R12, R16 R15 R62 R35, R44, R45 R48 to R51 R59 to R61 R63, R64 D1 U1 Inductor, 20 nH, 0402, 5% Inductor, 10 H, 0805, LQM series Resistor, 0 , 1/16 W, 1%, 0402 Resistor, 0402, spacing (do not install) Resistor, 4.7 k, 1/10 W, 1%, 0603 Resistor, 160 , 1/16 W, 1%, 0603 Resistor, 150 , 1/16 W, 1%, 0603 Resistor, 0603, spacing (do not install) Resistor, 51 , 1/16 W, 5%, 0402 Resistor, 330 , 1/10 W, 5%, 0805 Resistor, 100 , 1/10 W, 5%, 0805 Resistor, 100 k, 1/16 W, 1%, 0603 LED, red, 0805, 1.8 V, low current IC 24LC32A-I/MS EEPROM MSOP-8 TE Connectivity Vishay Multicomp FEC 1813421 FEC 8820201 FEC 1828912 FEC 8819556 FEC 8819572 142-0701-851 FEC 148533 and FEC 150411 FEC 1265424 FEC 1653752 FEC 1357983 Bourns Multicomp Multicomp FEC 2008358 FEC 9330658 FEC 9330593 Bourns Vishay Vishay Multicomp Rohm Microchip FEC 2008358 FEC 1739223 FEC 1652907 FEC 9330402 FEC 1685056 FEC 133-4660 14 Rev. B | Page 44 of 48 Data Sheet ADRF6755 OUTLINE DIMENSIONS 0.30 0.23 0.18 0.60 MAX 0.60 MAX 43 PIN 1 INDICATOR 7.85 7.75 SQ 7.65 1 0.50 BSC 6.65 6.50 SQ 6.35 EXPOSED PAD 29 TOP VIEW 1.00 0.85 0.80 0.80 MAX 0.65 TYP 12 MAX SEATING PLANE SIDE VIEW PIN 1 INDICATOR 56 42 0.50 0.40 0.30 14 28 15 BOTTOM VIEW 0.20 MIN 6.50 REF 0.05 MAX 0.02 NOM COPLANARITY 0.20 REF 0.08 FOR PROPER CONNECTION OF THE EXPOSED PAD, REFER TO THE PIN CONFIGURATION AND FUNCTION DESCRIPTIONS SECTION OF THIS DATA SHEET. COMPLIANT TO JEDEC STANDARDS MO-220-VLLD-2 06-11-2012-A 8.10 8.00 SQ 7.90 Figure 78. 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ] 8 mm x 8 mm Body, Very Thin Quad (CP-56-4) Dimensions shown in millimeters ORDERING GUIDE Model1, 2 ADRF6755ACPZ ADRF6755ACPZ-R7 EVAL-ADRF6755SDZ EVAL-SDP-CS1Z EVAL-SDP-CB1Z 1 2 Temperature Range -40C to +85C -40C to +85C Package Description 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ], Tray 56-Lead Lead Frame Chip Scale Package [LFCSP_VQ], 7" Tape and Reel Evaluation Board SDP-S Controller Board; Interface to EVAL-ADRF6755SDZ (also required) SDP-B Controller Board; Interface to EVAL-ADRF6755SDZ (alternative solution) Z = RoHS Compliant Part. Choose either EVAL-SDP-CS1Z or EVAL-SDP-CB1Z as EVAL-ADRF6755SDZ interface solution. Rev. B | Page 45 of 48 Package Option CP-56-4 CP-56-4 ADRF6755 Data Sheet NOTES Rev. B | Page 46 of 48 Data Sheet ADRF6755 NOTES Rev. B | Page 47 of 48 ADRF6755 Data Sheet NOTES I2C refers to a communications protocol originally developed by Philips Semiconductors (now NXP Semiconductors). (c)2012-2013 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D10465-0-4/13(B) Rev. B | Page 48 of 48 Mouser Electronics Authorized Distributor Click to View Pricing, Inventory, Delivery & Lifecycle Information: Analog Devices Inc.: ADRF6755ACPZ ADRF6755ACPZ-R7 EVAL-ADRF6755SDZ