12-Output Clock Generator with Integrated 1.6 GHz VCO AD9517-4 Data Sheet FUNCTIONAL BLOCK DIAGRAM APPLICATIONS Low jitter, low phase noise clock distribution 10/40/100 Gb/sec networking line cards, including SONET, Synchronous Ethernet, OTU2/3/4 Forward error correction (G.710) Clocking high speed ADCs, DACs, DDSs, DDCs, DUCs, MxFEs High performance wireless transceivers ATE and high performance instrumentation GENERAL DESCRIPTION The AD9517-41 provides a multi-output clock distribution function with subpicosecond jitter performance, along with an on-chip PLL and VCO. The on-chip VCO tunes from 1.45 GHz to 1.80 GHz. Optionally, an external VCO/VCXO of up to 2.4 GHz can be used. The AD9517-4 emphasizes low jitter and phase noise to maximize data converter performance, and it can benefit other applications with demanding phase noise and jitter requirements. Rev. E CP REFIN REF2 LF STATUS MONITOR PLL REF1 SWITCHOVER AND MONITOR Low phase noise, phase-locked loop (PLL) On-chip VCO tunes from 1.45 GHz to 1.80 GHz External VCO/VCXO to 2.4 GHz optional 1 differential or 2 single-ended reference inputs Reference monitoring capability Automatic revertive and manual reference switchover/holdover modes Accepts LVPECL, LVDS, or CMOS references to 250 MHz Programmable delays in path to PFD Digital or analog lock detect, selectable 2 pairs of 1.6 GHz LVPECL outputs Each output pair shares a 1-to-32 divider with coarse phase delay Additive output jitter: 225 fs rms Channel-to-channel skew paired outputs of <10 ps 2 pairs of 800 MHz LVDS clock outputs Each output pair shares two cascaded 1-to-32 dividers with coarse phase delay Additive output jitter: 275 fs rms Fine delay adjust (Δt) on each LVDS output Each LVDS output can be reconfigured as two 250 MHz CMOS outputs Automatic synchronization of all outputs on power-up Manual output synchronization available Available in a 48-lead LFCSP VCO DIVIDER AND MUXs CLK DIV/Φ LVPECL DIV/Φ DIV/Φ DIV/Φ DIV/Φ DIV/Φ LVPECL Δt Δt Δt Δt SERIAL CONTROL PORT AND DIGITAL LOGIC LVDS/CMOS LVDS/CMOS OUT0 OUT1 OUT2 OUT3 OUT4 OUT5 OUT6 OUT7 AD9517-4 06428-001 FEATURES Figure 1. The AD9517-4 features four LVPECL outputs (in two pairs) and four LVDS outputs (in two pairs). Each LVDS output can be reconfigured as two CMOS outputs. The LVPECL outputs operate to 1.6 GHz, the LVDS outputs operate to 800 MHz, and the CMOS outputs operate to 250 MHz. For applications that require additional outputs, a crystal reference input, zero-delay, or EEPROM for automatic configuration at startup, the AD9520 and AD9522 are available. In addition, the AD9516 and AD9518 are similar to the AD9517 but have a different combination of outputs. Each pair of outputs has dividers that allow both the divide ratio and coarse delay (or phase) to be set. The range of division for the LVPECL outputs is 1 to 32. The LVDS/CMOS outputs allow a range of divisions up to a maximum of 1024. The AD9517-4 is available in a 48-lead LFCSP and can be operated from a single 3.3 V supply. An external VCO, which requires an extended voltage range, can be accommodated by connecting the charge pump supply (VCP) to 5 V. A separate LVPECL power supply can be from 2.5 V to 3.3 V (nominal). The AD9517-4 is specified for operation over the industrial range of −40°C to +85°C. 1 AD9517 is used throughout the data sheet to refer to all the members of the AD9517 family. However, when AD9517-4 is used, it refers to that specific member of the AD9517 family. 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. 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Technical Support www.analog.com AD9517-4 Data Sheet TABLE OF CONTENTS Features .............................................................................................. 1 ESD Caution................................................................................ 17 Applications ....................................................................................... 1 Pin Configuration and Function Descriptions........................... 18 General Description ......................................................................... 1 Typical Performance Characteristics ........................................... 20 Functional Block Diagram .............................................................. 1 Terminology .................................................................................... 26 Revision History ............................................................................... 3 Detailed Block Diagram ................................................................ 27 Specifications..................................................................................... 4 Theory of Operation ...................................................................... 28 Power Supply Requirements ....................................................... 4 Operational Configurations ...................................................... 28 PLL Characteristics ...................................................................... 4 Digital Lock Detect (DLD) ....................................................... 37 Clock Inputs .................................................................................. 6 Clock Distribution ..................................................................... 41 Clock Outputs ............................................................................... 6 Reset Modes ................................................................................ 49 Timing Characteristics ................................................................ 8 Power-Down Modes .................................................................. 50 Clock Output Additive Phase Noise (Distribution Only; VCO Divider Not Used) .............................................................. 9 Serial Control Port ......................................................................... 51 Clock Output Absolute Phase Noise (Internal VCO Used) .. 10 General Operation of Serial Control Port ............................... 51 Clock Output Absolute Time Jitter (Clock Generation Using Internal VCO) .................................................................. 11 The Instruction Word (16 Bits) ................................................ 52 Clock Output Absolute Time Jitter (Clock Cleanup Using Internal VCO) .................................................................. 11 Thermal Performance .................................................................... 55 Clock Output Absolute Time Jitter (Clock Generation Using External VCXO) .............................................................. 11 Control Registers ............................................................................ 56 Control Register Map Overview .............................................. 56 Clock Output Additive Time Jitter (VCO Divider Not Used)..................................................................................... 12 Control Register Map Descriptions ......................................... 59 Applications Information .............................................................. 76 Clock Output Additive Time Jitter (VCO Divider Used) ..... 12 Frequency Planning Using the AD9517 .................................. 76 Delay Block Additive Time Jitter .............................................. 13 Using the AD9517 Outputs for ADC Clock Applications .... 76 Serial Control Port ..................................................................... 13 LVPECL Clock Distribution ..................................................... 77 PD, SYNC, and RESET Pins ..................................................... 14 LVDS Clock Distribution .......................................................... 77 LD, STATUS, and REFMON Pins ............................................ 14 CMOS Clock Distribution ........................................................ 78 Power Dissipation ....................................................................... 15 Outline Dimensions ....................................................................... 79 Timing Diagrams ............................................................................ 16 Ordering Guide .......................................................................... 79 Serial Control Port Pin Descriptions ....................................... 51 MSB/LSB First Transfers ........................................................... 52 Absolute Maximum Ratings.......................................................... 17 Thermal Resistance .................................................................... 17 Rev. E | Page 2 of 80 Data Sheet AD9517-4 REVISION HISTORY 3/13—Rev. D to Rev. E Changes to Table 52 ........................................................................ 57 Changes to Table 57 ........................................................................ 70 1/12—Rev. C to Rev. D Changes to Table 62 ........................................................................75 5/11—Rev. B to Rev. C Changes to Features, Applications, and General Description Sections ............................................................................................... 1 Change to CPRSET Pin Resistor Parameter, Table 1 .................... 4 Changes to Table 2 ............................................................................ 4 Changes to Table 4 ............................................................................ 6 Changes to Logic 1 Current and Logic 0 Current Parameters, Table 15 .......................................................................14 Changes to Table 20 ........................................................................18 Change to Caption, Figure 8 ..........................................................20 Change to Caption, Figure 15 ........................................................21 Change to Captions, Figure 25 and Figure 26 .............................23 Added Figure 41; Renumbered Sequentially ...............................25 Changes to On-Chip VCO Section ...............................................34 Changes to Reference Switchover Section ...................................35 Changes to Prescaler Section and Change to Comments/Conditions Column, Table 28 ...................................36 Changes to Automatic/Internal Holdover Mode Section and Frequency Status Monitors Section .......................................39 Changes to VCO Calibration Section ...........................................40 Changes to Clock Distribution Section ........................................41 Changes to Write Section ...............................................................51 Change to The Instruction Word (16 Bits) Section ....................52 Change to Figure 65 ........................................................................53 Change to Thermal Performance Section ....................................55 Changes to Register Address 0x01C, Bits[4:3], Table 52............56 Changes to Address 0x017, Bits[1:0] and Address 0x018, Bits[2:0], Table 54 ............................................................................62 Changes to Register Address 0x01C, Bits[5:1], Table 54............64 Change to LVPECL Clock Distribution Section .........................77 5/10—Rev. A to Rev. B Changes to Default Values of LVDS/CMOS Outputs Section in Table 52 ..........................................................................56 Changes to Register 0x140, Bit 0; Register 0x142, Bit 0; Register 0x143, Bit 0 in Table 57 ...................................................69 Updated Outline Dimensions, Changes to Ordering Guide .....78 1/10—Rev. 0 to Rev. A Added 48-Lead LFCSP Package (CP-48-8) .................... Universal Changes to Features, Applications, and General Description..... 1 Change to CPRSET Pin Resistor Parameter .................................. 4 Changes to Table 4 ............................................................................ 6 Changes to VCP Supply Parameter................................................. 14 Changes to Table 19 ........................................................................ 16 Added Exposed Paddle Notation to Figure 6; Changes to Table 20 ............................................................................................. 17 Change to High Frequency Clock Distribution—CLK or External VCO > 1600 MHz Section; Change to Table 22 .......... 27 Changes to Table 24 ........................................................................ 29 Change to Configuration and Register Settings Section ........... 31 Change to Phase Frequency Detector (PFD) Section ................ 32 Changes to Charge Pump (CP), On-Chip VCO, PLL External Loop Filter, and PLL Reference Inputs Sections ......... 33 Change to Figure 46; Added Figure 47......................................... 33 Changes to Reference Switchover and VCXO/VCO Feedback Divider N—P, A, B, R Sections .................................... 34 Changes to Table 28 ........................................................................ 35 Change to Holdover Section .......................................................... 37 Changes to VCO Calibration Section........................................... 39 Changes to Clock Distribution Section........................................ 40 Change to Clock Frequency Division Section; Change to Table 34 .......................................................................... 41 Changes to Channel Dividers—LVDS/CMOS Outputs Section; Change to Table 39 ........................................................... 43 Change to Write Section ................................................................ 50 Change to MSB/LSB First Transfers ............................................. 51 Change to Figure 64 ........................................................................ 52 Added Thermal Performance Section .......................................... 54 Changes to 0x003 Register Address .............................................. 55 Changes to Table 53 ........................................................................ 58 Changes to Table 54 ........................................................................ 59 Changes to Table 55 ........................................................................ 65 Changes to Table 56 ........................................................................ 67 Changes to Table 57 ........................................................................ 69 Changes to Table 58 ........................................................................ 71 Changes to Table 59 ........................................................................ 72 Changes to Table 60 and Table 61 ................................................. 74 Added Frequency Planning Using the AD9517 Section ............ 75 Changes to Figure 70 and Figure 72; Added Figure 71 .............. 76 Changes to LVDS Clock Distribution Section ............................ 76 Added Exposed Paddle Notation to Outline Dimensions ......... 78 Changes to Ordering Guide ........................................................... 78 7/07—Revision 0: Initial Version Rev. E | Page 3 of 80 AD9517-4 Data Sheet SPECIFICATIONS Typical is given for VS = VS_LVPECL = 3.3 V ± 5%; VS ≤ VCP ≤ 5.25 V; TA = 25°C; RSET = 4.12 kΩ; CPRSET = 5.1 kΩ, unless otherwise noted. Minimum and maximum values are given over full VS and TA (−40°C to +85°C) variation. POWER SUPPLY REQUIREMENTS Table 1. Parameter VS VS_LVPECL VCP RSET Pin Resistor CPRSET Pin Resistor Min 3.135 2.375 VS 2.7 BYPASS Pin Capacitor Typ 3.3 4.12 5.1 Max 3.465 VS 5.25 10 220 Unit V V V kΩ kΩ nF Test Conditions/Comments 3.3 V ± 5% Nominally 2.5 V to 3.3 V ± 5% Nominally 3.3 V to 5.0 V ± 5% Sets internal biasing currents; connect to ground Sets internal CP current range, nominally 4.8 mA (CP_lsb = 600 µA); actual current can be calculated by CP_lsb = 3.06/CPRSET; connect to ground Bypass for internal LDO regulator; necessary for LDO stability; connect to ground PLL CHARACTERISTICS Table 2. Parameter VCO (ON-CHIP) Frequency Range VCO Gain (KVCO) Tuning Voltage (VT) Min 1450 0.5 Input Capacitance Test Conditions/Comments 1800 MHz MHz/V V See Figure 15 See Figure 10 VCP ≤ VS when using internal VCO; outside of this range, the CP spurs may increase due to CP up/down mismatch VCP − 0.5 0 MHz/V dBc/Hz dBc/Hz 250 MHz 250 1.35 1.30 4.0 4.4 1.60 1.50 4.8 5.3 20 0 mV p-p 1.75 1.60 5.9 6.4 V V kΩ kΩ 250 250 MHz MHz V p-p V V µA ns 0.8 2.0 0.8 +100 −100 1.8 2 PHASE/FREQUENCY DETECTOR (PFD) PFD Input Frequency Antibacklash Pulse Width Unit 1 −109 −128 Input Sensitivity Self-Bias Voltage, REFIN Self-Bias Voltage, REFIN Input Resistance, REFIN Input Resistance, REFIN Dual Single-Ended Mode (REF1, REF2) Input Frequency (AC-Coupled) Input Frequency (DC-Coupled) Input Sensitivity (AC-Coupled) Input Logic High Input Logic Low Input Current Pulse Width High/Low Max 50 Frequency Pushing (Open Loop) Phase Noise at 100 kHz Offset Phase Noise at 1 MHz Offset REFERENCE INPUTS Differential Mode (REFIN, REFIN) Input Frequency Typ 100 45 1.3 2.9 6.0 f = 1625 MHz f = 1625 MHz Differential mode (can accommodate single-ended input by ac grounding undriven input) Frequencies below about 1 MHz should be dc-coupled; be careful to match VCM (self-bias voltage) PLL figure of merit (FOM) increases with increasing slew rate (see Figure 14); the input sensitivity is sufficient for ac-coupled LVDS and LVPECL signals Self-bias voltage of REFIN 1 Self-bias voltage of REFIN1 Self-biased1 Self-biased1 Two single-ended CMOS-compatible inputs Slew rate > 50 V/µs Slew rate > 50 V/µs; CMOS levels Should not exceed VS p-p pF This value determines the allowable input duty cycle and is the amount of time that a square wave is high/low Each pin, REFIN/REFIN (REF1/REF2) MHz MHz ns ns ns Antibacklash pulse width = 1.3 ns, 2.9 ns Antibacklash pulse width = 6.0 ns Register 0x017[1:0] = 01b Register 0x017[1:0] = 00b; Register 0x017[1:0] = 11b Register 0x017[1:0] = 10b Rev. E | Page 4 of 80 Data Sheet Parameter CHARGE PUMP (CP) ICP Sink/Source High Value Low Value Absolute Accuracy CPRSET Range ICP High Impedance Mode Leakage Sink-and-Source Current Matching ICP vs. CPV ICP vs. Temperature PRESCALER (PART OF N DIVIDER) Prescaler Input Frequency P = 1 FD P = 2 FD P = 3 FD P = 2 DM (2/3) P = 4 DM (4/5) P = 8 DM (8/9) P = 16 DM (16/17) P = 32 DM (32/33) Prescaler Output Frequency PLL DIVIDER DELAYS 000 001 010 011 100 101 110 111 NOISE CHARACTERISTICS In-Band Phase Noise of the Charge Pump/Phase Frequency Detector (In-Band Is Within the LBW of the PLL) At 500 kHz PFD Frequency At 1 MHz PFD Frequency At 10 MHz PFD Frequency At 50 MHz PFD Frequency PLL Figure of Merit (FOM) AD9517-4 Min Typ Max 4.8 0.60 2.5 2.7/1 0 1 2 1.5 2 mA mA % kΩ nA % % % 300 600 900 200 1000 2400 3000 3000 300 Off 330 440 550 660 770 880 990 Unit MHz MHz MHz MHz MHz MHz MHz MHz MHz 1 2 CPV = VCP/2 V 0.5 < CPV < VCP − 0.5 V 0.5 < CPV < VCP − 0.5 V CPV = VCP/2 V See the VCXO/VCO Feedback Divider N—P, A, B, R section A, B counter input frequency (prescaler input frequency divided by P) Register 0x019: R, Bits[5:3]; N, Bits[2:0]; see Table 54 ps ps ps ps ps ps ps ps The PLL in-band phase noise floor is estimated by measuring the in-band phase noise at the output of the VCO and subtracting 20 log(N) (where N is the value of the N divider) −165 −162 −151 −143 −220 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz 3.5 7.5 3.5 ns ns ns Reference slew rate > 0.25 V/ns; FOM +10 log(fPFD) is an approximation of the PFD/CP in-band phase noise (in the flat region) inside the PLL loop bandwidth; when running closed-loop, the phase noise, as observed at the VCO output, is increased by 20 log(N) Signal available at LD, STATUS, and REFMON pins when selected by appropriate register settings Selected by Register 0x017[1:0] and Register 0x018[4] Register 0x017[1:0] = 00b, 01b, 11b; Register 0x018[4] = 1b Register 0x017[1:0] = 00b, 01b, 11b; Register 0x018[4] = 0b Register 0x017[1:0] = 10b; Register 0x018[4] = 0b 7 15 11 ns ns ns Register 0x017[1:0] = 00b, 01b, 11b; Register 0x018[4] = 1b Register 0x017[1:0] = 00b, 01b, 11b; Register 0x018[4] = 0b Register 0x017[1:0] = 10b; Register 0x018[4] = 0b PLL DIGITAL LOCK DETECT WINDOW 2 Required to Lock (Coincidence of Edges) Low Range (ABP 1.3 ns, 2.9 ns) High Range (ABP 1.3 ns, 2.9 ns) High Range (ABP 6.0 ns) To Unlock After Lock (Hysteresis)2 Low Range (ABP 1.3 ns, 2.9 ns) High Range (ABP 1.3 ns, 2.9 ns) High Range (ABP 6.0 ns) Test Conditions/Comments CPV is CP pin voltage; VCP is charge pump power supply voltage Programmable With CPRSET = 5.1 kΩ REFIN and REFIN self-bias points are offset slightly to avoid chatter on an open input condition. For reliable operation of the digital lock detect, the period of the PFD frequency must be greater than the unlock-after-lock time. Rev. E | Page 5 of 80 AD9517-4 Data Sheet CLOCK INPUTS Table 3. Parameter CLOCK INPUTS (CLK, CLK) Input Frequency Min Typ 01 01 Input Sensitivity, Differential 1 Unit 2.4 1.6 GHz GHz mV p-p 2 V p-p 1.8 1.8 V V mV p-p kΩ pF 150 Input Level, Differential Input Common-Mode Voltage, VCM Input Common-Mode Range, VCMR Input Sensitivity, Single-Ended Input Resistance Input Capacitance Max 1.3 1.3 3.9 1.57 150 4.7 2 5.7 Test Conditions/Comments Differential input High frequency distribution (VCO divider) Distribution only (VCO divider bypassed) Measured at 2.4 GHz; jitter performance is improved with slew rates > 1 V/ns Larger voltage swings may turn on the protection diodes and may degrade jitter performance Self-biased; enables ac coupling With 200 mV p-p signal applied; dc-coupled CLK ac-coupled; CLK ac-bypassed to RF ground Self-biased Below about 1 MHz, the input should be dc-coupled. Care should be taken to match VCM. CLOCK OUTPUTS Table 4. Parameter LVPECL CLOCK OUTPUTS OUT0, OUT1, OUT2, OUT3 Output Frequency, Maximum Output High Voltage (VOH) Output Low Voltage (VOL) Output Differential Voltage (VOD) Min Typ 2950 VS_LVPECL − 1.12 VS_LVPECL − 2.03 550 247 VS_LVPECL − 0.84 VS_LVPECL − 1.49 980 V 800 MHz 454 mV 25 mV 1.24 1.375 25 V mV 14 24 mA VS_LVPECL − 0.98 VS_LVPECL − 1.77 790 360 Delta VOD Output Offset Voltage (VOS) Delta VOS Short-Circuit Current (ISA, ISB) 1.125 Unit MHz LVDS CLOCK OUTPUTS OUT4, OUT5, OUT6, OUT7 Output Frequency Output Differential Voltage (VOD) Max Test Conditions/Comments Termination = 50 Ω to VS − 2 V Differential (OUT, OUT) Using direct to output; see Figure 25 for peak-to-peak differential amplitude V mV Rev. E | Page 6 of 80 This is VOH − VOL for each leg of a differential pair for default amplitude setting with driver not toggling; the peak-to-peak amplitude measured using a differential probe across the differential pair with the driver toggling is roughly 2× these values (see Figure 25 for variation over frequency) Differential termination 100 Ω at 3.5 mA Differential (OUT, OUT) The AD9517 outputs toggle at higher frequencies, but the output amplitude may not meet the VOD specification; see Figure 26 VOH − VOL measurement across a differential pair at the default amplitude setting with output driver not toggling; see Figure 26 for variation over frequency This is the absolute value of the difference between VOD when the normal output is high vs. when the complementary output is high (VOH + VOL)/2 across a differential pair This is the absolute value of the difference between VOS when the normal output is high vs. when the complementary output is high Output shorted to GND Data Sheet Parameter CMOS CLOCK OUTPUTS OUT4A, OUT4B, OUT5A, OUT5B, OUT6A, OUT6B, OUT7A, OUT7B Output Frequency Output Voltage High (VOH) Low (VOL) Source Current Static Dynamic Sink Current Static Dynamic AD9517-4 Min Typ Max Unit Test Conditions/Comments Single-ended; termination = 10 pF 250 MHz See Figure 27 0.1 V V At 1 mA load At 1 mA load Exceeding these values can result in damage to the part 20 16 mA mA 8 16 mA mA VS − 0.1 Exceeding these values can result in damage to the part Rev. E | Page 7 of 80 AD9517-4 Data Sheet TIMING CHARACTERISTICS Table 5. Parameter LVPECL Output Rise Time, tRP Output Fall Time, tFP PROPAGATION DELAY, tPECL, CLK-TO-LVPECL OUTPUT High Frequency Clock Distribution Configuration Clock Distribution Configuration Variation with Temperature OUTPUT SKEW, LVPECL OUTPUTS 1 LVPECL Outputs That Share the Same Divider LVPECL Outputs on Different Dividers All LVPECL Outputs Across Multiple Parts LVDS Output Rise Time, tRL Output Fall Time, tFL PROPAGATION DELAY, tLVDS, CLK-TO-LVDS OUTPUT For All Divide Values Variation with Temperature OUTPUT SKEW, LVDS OUTPUTS1 LVDS Outputs That Share the Same Divider LVDS Outputs on Different Dividers All LVDS Outputs Across Multiple Parts CMOS Output Rise Time, tRC Output Fall Time, tFC PROPAGATION DELAY, tCMOS, CLK-TO-CMOS OUTPUT For All Divide Values Variation with Temperature OUTPUT SKEW, CMOS OUTPUTS1 CMOS Outputs That Share the Same Divider All CMOS Outputs on Different Dividers All CMOS Outputs Across Multiple Parts DELAY ADJUST 3 Shortest Delay Range 4 Zero Scale Full Scale Longest Delay Range4 Zero Scale Quarter Scale Full Scale Delay Variation with Temperature Short Delay Range5 Zero Scale Full Scale Long Delay Range 5 Zero Scale Full Scale Min 835 773 1.4 Typ Max Unit 70 70 180 180 ps ps 995 933 0.8 1180 1090 ps ps ps/°C 5 13 15 40 220 ps ps ps 170 160 350 350 ps ps 1.8 1.25 2.1 ns ps/°C 6 25 62 150 430 ps ps ps 495 475 1000 985 ps ps 2.1 2.6 2.6 ns ps/°C 4 28 66 180 675 ps ps ps Test Conditions/Comments Termination = 50 Ω to VS − 2 V; level = 810 mV 20% to 80%, measured differentially 80% to 20%, measured differentially See Figure 43 See Figure 45 Termination = 100 Ω differential; 3.5 mA 20% to 80%, measured differentially 2 20% to 80%, measured differentially2 Delay off on all outputs Delay off on all outputs 1.6 Termination = open 20% to 80%; CLOAD = 10 pF 80% to 20%; CLOAD = 10 pF Fine delay off Fine delay off 50 540 315 880 680 1180 ps ps 200 1.72 5.7 570 2.31 8.0 950 2.89 10.1 ps ns ns 0.23 −0.02 ps/°C ps/°C 0.3 0.24 ps/°C ps/°C LVDS and CMOS Register 0x0A1 (0x0A4, 0x0A7, 0x0AA), Bits[5:0] = 101111b Register 0x0A2 (0x0A5, 0x0A8, 0x0AB), Bits[5:0] = 000000b Register 0x0A2 (0x0A5, 0x0A8, 0x0AB), Bits[5:0] = 101111b Register 0x0A1 (0x0A4, 0x0A7, 0x0AA), Bits[5:0] = 000000b Register 0x0A2 (0x0A5, 0x0A8, 0x0AB), Bits[5:0] = 000000b Register 0x0A2 (0x0A5, 0x0A8, 0x0AB), Bits[5:0] = 001100b Register 0x0A2 (0x0A5, 0x0A8, 0x0AB), Bits[5:0] = 101111b This is the difference between any two similar delay paths while operating at the same voltage and temperature. Corresponding CMOS drivers set to A for noninverting and B for inverting. The maximum delay that can be used is a little less than one-half the period of the clock. A longer delay disables the output. 4 Incremental delay; does not include propagation delay. 5 All delays between zero scale and full scale can be estimated by linear interpolation. 1 2 3 Rev. E | Page 8 of 80 Data Sheet AD9517-4 CLOCK OUTPUT ADDITIVE PHASE NOISE (DISTRIBUTION ONLY; VCO DIVIDER NOT USED) Table 6. Parameter CLK-TO-LVPECL ADDITIVE PHASE NOISE CLK = 1 GHz, Output = 1 GHz Divider = 1 At 10 Hz Offset At 100 Hz Offset At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset At 10 MHz Offset At 100 MHz Offset CLK = 1 GHz, Output = 200 MHz Divider = 5 At 10 Hz Offset At 100 Hz Offset At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset >10 MHz Offset CLK-TO-LVDS ADDITIVE PHASE NOISE CLK = 1.6 GHz, Output = 800 MHz Divider = 2 At 10 Hz Offset At 100 Hz Offset At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset At 10 MHz Offset At 100 MHz Offset CLK = 1.6 GHz, Output = 400 MHz Divider = 4 At 10 Hz Offset At 100 Hz Offset At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset >10 MHz Offset CLK-TO-CMOS ADDITIVE PHASE NOISE CLK = 1 GHz, Output = 250 MHz Divider = 4 At 10 Hz Offset At 100 Hz Offset At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset >10 MHz Offset Min Typ −109 −118 −130 −139 −144 −146 −147 −149 Max Unit Test Conditions/Comments Distribution section only; does not include PLL and VCO Input slew rate > 1 V/ns dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz Input slew rate > 1 V/ns −120 −126 −139 −150 −155 −157 −157 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz Distribution section only; does not include PLL and VCO Input slew rate > 1 V/ns −103 −110 −120 −127 −133 −138 −147 −149 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz Input slew rate > 1 V/ns −114 −122 −132 −140 −146 −150 −155 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz Distribution section only; does not include PLL and VCO Input slew rate > 1 V/ns −110 −120 −127 −136 −144 −147 −154 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz Rev. E | Page 9 of 80 AD9517-4 Parameter CLK = 1 GHz, Output = 50 MHz Divider = 20 At 10 Hz Offset At 100 Hz Offset At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset >10 MHz Offset Data Sheet Min Typ Max −124 −134 −142 −151 −157 −160 −163 Unit Test Conditions/Comments Input slew rate > 1 V/ns dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz CLOCK OUTPUT ABSOLUTE PHASE NOISE (INTERNAL VCO USED) Table 7. Parameter LVPECL ABSOLUTE PHASE NOISE VCO = 1800 MHz; Output = 1800 MHz At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset At 10 MHz Offset At 40 MHz Offset VCO = 1625 MHz; Output = 1625 MHz At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset At 10 MHz Offset At 40 MHz Offset VCO = 1450 MHz; Output = 1450 MHz At 1 kHz Offset At 10 kHz Offset At 100 kHz Offset At 1 MHz Offset At 10 MHz Offset At 40 MHz Offset Min Typ Max Unit −47 −82 −106 −125 −142 −146 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz −55 −85 −109 −128 −143 −147 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz −61 −90 −113 −131 −144 −148 dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz dBc/Hz Rev. E | Page 10 of 80 Test Conditions/Comments Internal VCO; direct to LVPECL output Data Sheet AD9517-4 CLOCK OUTPUT ABSOLUTE TIME JITTER (CLOCK GENERATION USING INTERNAL VCO) Table 8. Parameter LVPECL OUTPUT ABSOLUTE TIME JITTER Min VCO = 1475 MHz; LVPECL = 491.52 MHz; PLL LBW = 135 kHz Typ Max 135 275 145 275 170 305 VCO = 1475 MHz; LVPECL = 122.88 MHz; PLL LBW = 135 kHz VCO = 1475 MHz; LVPECL = 61.44 MHz; PLL LBW = 135 kHz Unit fs rms fs rms fs rms fs rms fs rms fs rms Test Conditions/Comments Application example based on a typical setup where the reference source is clean, so a wider PLL loop bandwidth is used; reference = 15.36 MHz; R = 1 Integration BW = 200 kHz to 10 MHz Integration BW = 12 kHz to 20 MHz Integration BW = 200 kHz to 10 MHz Integration BW = 12 kHz to 20 MHz Integration BW = 200 kHz to 10 MHz Integration BW = 12 kHz to 20 MHz CLOCK OUTPUT ABSOLUTE TIME JITTER (CLOCK CLEANUP USING INTERNAL VCO) Table 9. Parameter LVPECL OUTPUT ABSOLUTE TIME JITTER Min VCO = 1555 MHz; LVPECL = 155.52 MHz; PLL LBW = 500 Hz VCO = 1475 MHz; LVPECL = 122.88 MHz; PLL LBW = 500 Hz Typ Max 500 400 Unit fs rms fs rms Test Conditions/Comments Application example based on a typical setup where the reference source is jittery, so a narrower PLL loop bandwidth is used; reference = 10.0 MHz; R = 20 Integration BW = 12 kHz to 20 MHz Integration BW = 12 kHz to 20 MHz CLOCK OUTPUT ABSOLUTE TIME JITTER (CLOCK GENERATION USING EXTERNAL VCXO) Table 10. Parameter LVPECL OUTPUT ABSOLUTE TIME JITTER LVPECL = 245.76 MHz; PLL LBW = 125 Hz LVPECL = 122.88 MHz; PLL LBW = 125 Hz LVPECL = 61.44 MHz; PLL LBW = 125 Hz Min Typ 54 77 109 79 114 163 124 176 259 Rev. E | Page 11 of 80 Max Unit fs rms fs rms fs rms fs rms fs rms fs rms fs rms fs rms fs rms Test Conditions/Comments Application example based on a typical setup using an external 245.76 MHz VCXO (Toyocom TCO-2112); reference = 15.36 MHz; R=1 Integration BW = 200 kHz to 5 MHz Integration BW = 200 kHz to 10 MHz Integration BW = 12 kHz to 20 MHz Integration BW = 200 kHz to 5 MHz Integration BW = 200 kHz to 10 MHz Integration BW = 12 kHz to 20 MHz Integration BW = 200 kHz to 5 MHz Integration BW = 200 kHz to 10 MHz Integration BW = 12 kHz to 20 MHz AD9517-4 Data Sheet CLOCK OUTPUT ADDITIVE TIME JITTER (VCO DIVIDER NOT USED) Table 11. Parameter LVPECL OUTPUT ADDITIVE TIME JITTER Min Typ Max Unit CLK = 622.08 MHz; LVPECL = 622.08 MHz; Divider = 1 CLK = 622.08 MHz; LVPECL = 155.52 MHz; Divider = 4 CLK = 1.6 GHz; LVPECL = 100 MHz; Divider = 16 40 80 215 fs rms fs rms fs rms CLK = 500 MHz; LVPECL = 100 MHz; Divider = 5 245 fs rms 85 fs rms 113 280 fs rms fs rms 365 fs rms LVDS OUTPUT ADDITIVE TIME JITTER CLK = 1.6 GHz; LVDS = 800 MHz; Divider = 2; VCO Divider Not Used CLK = 1 GHz; LVDS = 200 MHz; Divider = 5 CLK = 1.6 GHz; LVDS = 100 MHz; Divider = 16 CMOS OUTPUT ADDITIVE TIME JITTER CLK = 1.6 GHz; CMOS = 100 MHz; Divider = 16 Test Conditions/Comments Distribution section only; does not include PLL and VCO; uses rising edge of clock signal BW = 12 kHz to 20 MHz BW = 12 kHz to 20 MHz Calculated from SNR of ADC method; DCC not used for even divides Calculated from SNR of ADC method; DCC on Distribution section only; does not include PLL and VCO; uses rising edge of clock signal BW = 12 kHz to 20 MHz BW = 12 kHz to 20 MHz Calculated from SNR of ADC method; DCC not used for even divides Distribution section only; does not include PLL and VCO; uses rising edge of clock signal Calculated from SNR of ADC method; DCC not used for even divides CLOCK OUTPUT ADDITIVE TIME JITTER (VCO DIVIDER USED) Table 12. Parameter LVPECL OUTPUT ADDITIVE TIME JITTER Min Typ CLK = 2.4 GHz; VCO DIV = 2; LVPECL = 100 MHz; Divider = 12; Duty-Cycle Correction = Off LVDS OUTPUT ADDITIVE TIME JITTER 210 CLK = 2.4 GHz; VCO DIV = 2; LVDS = 100 MHz; Divider = 12; Duty-Cycle Correction = Off CMOS OUTPUT ADDITIVE TIME JITTER 285 CLK = 2.4 GHz; VCO DIV = 2; CMOS = 100 MHz; Divider = 12; Duty-Cycle Correction = Off Max 350 Rev. E | Page 12 of 80 Unit fs rms Test Conditions/Comments Distribution section only; does not include PLL and VCO; uses rising edge of clock signal Calculated from SNR of ADC method fs rms Distribution section only; does not include PLL and VCO; uses rising edge of clock signal Calculated from SNR of ADC method fs rms Distribution section only; does not include PLL and VCO; uses rising edge of clock signal Calculated from SNR of ADC method Data Sheet AD9517-4 DELAY BLOCK ADDITIVE TIME JITTER Table 13. Parameter DELAY BLOCK ADDITIVE TIME JITTER 1 100 MHz Output Delay (1600 µA, 0x1C) Fine Adj. 000000b Delay (1600 µA, 0x1C) Fine Adj. 101111b Delay (800 µA, 0x1C) Fine Adj. 000000b Delay (800 µA, 0x1C) Fine Adj. 101111b Delay (800 µA, 0x4C) Fine Adj. 000000b Delay (800 µA, 0x4C) Fine Adj. 101111b Delay (400 µA, 0x4C) Fine Adj. 000000b Delay (400 µA, 0x4C) Fine Adj. 101111b Delay (200 µA, 0x1C) Fine Adj. 000000b Delay (200 µA, 0x1C) Fine Adj. 101111b Delay (200 µA, 0x4C) Fine Adj. 000000b Delay (200 µA, 0x4C) Fine Adj. 101111b 1 Min Typ Max 0.54 0.60 0.65 0.85 0.79 1.2 1.2 2.0 1.3 2.5 1.9 3.8 Unit Test Conditions/Comments Incremental additive jitter ps rms ps rms ps rms ps rms ps rms ps rms ps rms ps rms ps rms ps rms ps rms ps rms This value is incremental. That is, it is in addition to the jitter of the LVDS or CMOS output without the delay. To estimate the total jitter, the LVDS or CMOS output jitter should be added to this value using the root sum of the squares (RSS) method. SERIAL CONTROL PORT Table 14. Parameter CS (INPUT) Input Logic 1 Voltage Input Logic 0 Voltage Input Logic 1 Current Input Logic 0 Current Input Capacitance SCLK (INPUT) Input Logic 1 Voltage Input Logic 0 Voltage Input Logic 1 Current Input Logic 0 Current Input Capacitance SDIO (WHEN INPUT) Input Logic 1 Voltage Input Logic 0 Voltage Input Logic 1 Current Input Logic 0 Current Input Capacitance SDIO, SDO (OUTPUTS) Output Logic 1 Voltage Output Logic 0 Voltage TIMING Clock Rate (SCLK, 1/tSCLK) Pulse Width High, tHIGH Pulse Width Low, tLOW SDIO to SCLK Setup, tDS SCLK to SDIO Hold, tDH SCLK to Valid SDIO and SDO, tDV CS to SCLK Setup and Hold, tS, tH CS Minimum Pulse Width High, tPWH Min Typ Max 2.0 0.8 3 110 2 Unit Test Conditions/Comments CS has an internal 30 kΩ pull-up resistor V V µA µA pF SCLK has an internal 30 kΩ pull-down resistor 2.0 0.8 110 1 2 2.0 0.8 10 20 2 2.7 0.4 25 16 16 2 1.1 8 2 3 V V µA µA pF V V nA nA pF V V MHz ns ns ns ns ns ns ns Rev. E | Page 13 of 80 AD9517-4 Data Sheet PD, SYNC, AND RESET PINS Table 15. Parameter INPUT CHARACTERISTICS Min Logic 1 Voltage Logic 0 Voltage Logic 1 Current Logic 0 Current Capacitance RESET TIMING Pulse Width Low SYNC TIMING Pulse Width Low 2.0 Typ Max 0.8 1 110 2 Unit Test Conditions/Comments These pins each have a 30 kΩ internal pull-up resistor V V µA µA pF 50 ns 1.5 High speed clock cycles High speed clock is CLK input signal Max Unit Test Conditions/Comments When selected as a digital output (CMOS); there are other modes in which these pins are not CMOS digital outputs; see Table 54, Register 0x017, Register 0x01A, and Register 0x01B 0.4 100 V V MHz 3 pF On-chip capacitance; used to calculate RC time constant for analog lock detect readback; use a pull-up resistor 1.02 MHz 8 kHz Frequency above which the monitor always indicates the presence of the reference Frequency above which the monitor always indicates the presence of the reference LD, STATUS, AND REFMON PINS Table 16. Parameter OUTPUT CHARACTERISTICS Min Output Voltage High (VOH) Output Voltage Low (VOL) MAXIMUM TOGGLE RATE 2.7 ANALOG LOCK DETECT Capacitance REF1, REF2, AND VCO FREQUENCY STATUS MONITOR Normal Range Extended Range (REF1 and REF2 Only) LD PIN COMPARATOR Trip Point Hysteresis Typ 1.6 260 Rev. E | Page 14 of 80 V mV Applies when mux is set to any divider or counter output, or PFD up/down pulse; also applies in analog lock detect mode; usually debug mode only; beware that spurs may couple to output when any of these pins are toggling Data Sheet AD9517-4 POWER DISSIPATION Table 17. Parameter POWER DISSIPATION, CHIP Power-On Default Typ Max Unit Test Conditions/Comments 1.0 1.2 W Full Operation; CMOS Outputs at 229 MHz 1.4 2.0 W Full Operation; LVDS Outputs at 200 MHz 1.4 2.1 W PD Power-Down 75 185 mW PD Power-Down, Maximum Sleep 31 No clock; no programming; default register values; does not include power dissipated in external resistors PLL on; internal VCO = 2750 MHz; VCO divider = 2; all channel dividers on; four LVPECL outputs at 687.5 MHz; eight CMOS outputs (10 pF load) at 229 MHz; all fine delay on, maximum current; does not include power dissipated in external resistors PLL on; internal VCO = 2800 MHz, VCO divider = 2; all channel dividers on; four LVPECL outputs at 700 MHz; four LVDS outputs at 200 MHz; all fine delay on, maximum current; does not include power dissipated in external resistors PD pin pulled low; does not include power dissipated in terminations PD pin pulled low; PLL power-down, Register 0x010[1:0] = 01b; SYNC power-down, Register 0x230[2] = 1b; REF for distribution power-down, Register 0x230[1] = 1b PLL operating; typical closed-loop configuration Power delta when a function is enabled/disabled VCO divider bypassed All references off to differential reference enabled All references off to REF1 or REF2 enabled; differential reference not enabled CLK input selected to VCO selected PLL off to PLL on, normal operation; no reference enabled Divider bypassed to divide-by-2 to divide-by-32 No LVPECL output on to one LVPECL output on, independent of frequency Second LVPECL output turned on, same channel No LVDS output on to one LVDS output on; see Figure 8 for dependence on output frequency Second LVDS output turned on, same channel Static; no CMOS output on to one CMOS output on; see Figure 9 for variation over output frequency Static; second CMOS output, same pair, turned on Static; first output, second pair, turned on Delay block off to delay block enabled; maximum current setting VCP Supply POWER DELTAS, INDIVIDUAL FUNCTIONS VCO Divider REFIN (Differential) REF1, REF2 (Single-Ended) Min 4 mW 4.8 mW 30 20 4 mW mW mW VCO PLL Channel Divider LVPECL Channel (Divider Plus Output Driver) 70 75 30 160 mW mW mW mW LVPECL Driver LVDS Channel (Divider Plus Output Driver) 90 120 mW mW LVDS Driver CMOS Channel (Divider Plus Output Driver) 50 100 mW mW CMOS Driver (Second in Pair) CMOS Driver (First in Second Pair) Fine Delay Block 0 30 50 mW mW mW Rev. E | Page 15 of 80 AD9517-4 Data Sheet TIMING DIAGRAMS tCLK CLK DIFFERENTIAL tPECL 80% LVDS tRL 06428-060 tCMOS tFL 06428-062 20% tLVDS Figure 4. LVDS Timing, Differential Figure 2. CLK/CLK to Clock Output Timing, DIV = 1 DIFFERENTIAL SINGLE-ENDED 80% 80% LVPECL CMOS 10pF LOAD 20% tFP tRC tFC Figure 5. CMOS Timing, Single-Ended, 10 pF Load Figure 3. LVPECL Timing, Differential Rev. E | Page 16 of 80 06428-063 tRP 06428-061 20% Data Sheet AD9517-4 ABSOLUTE MAXIMUM RATINGS Table 18. Parameter VS, VS_LVPECL to GND VCP to GND REFIN, REFIN to GND REFIN to REFIN RSET to GND CPRSET to GND CLK, CLK to GND CLK to CLK SCLK, SDIO, SDO, CS to GND OUT0, OUT0, OUT1, OUT1, OUT2, OUT2, OUT3, OUT3,OUT4, OUT4, OUT5, OUT5, OUT6, OUT6, OUT7, OUT7 to GND SYNC to GND REFMON, STATUS, LD to GND Junction Temperature 1 Storage Temperature Range Lead Temperature (10 sec) 1 Rating −0.3 V to +3.6 V −0.3 V to +5.8 V −0.3 V to VS + 0.3 V −3.3 V to +3.3 V −0.3 V to VS + 0.3 V −0.3 V to VS + 0.3 V −0.3 V to VS + 0.3 V −1.2 V to +1.2 V −0.3 V to VS + 0.3 V −0.3 V to VS + 0.3 V −0.3 V to VS + 0.3 V −0.3 V to VS + 0.3 V 150°C −65°C to +150°C 300°C 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. THERMAL RESISTANCE Table 19. Package Type1 48-Lead LFCSP 1 θJA 24.7 Unit °C/W Thermal impedance measurements were taken on a 4-layer board in still air in accordance with EIA/JESD51-2. ESD CAUTION See Table 19 for θJA. Rev. E | Page 17 of 80 AD9517-4 Data Sheet 1 37 VS 39 OUT1 38 OUT1 40 VS_LVPECL 42 OUT0 41 OUT0 44 RSET 45 VS 47 REFIN (REF2) 43 VS 36 PIN 1 INDICATOR 2 VS 35 OUT4 (OUT4A) 3 34 OUT4 (OUT4B) 4 33 OUT5 (OUT5A) 32 OUT5 (OUT5B) 5 6 AD9517-4 31 VS 7 TOP VIEW (Not to Scale) 30 VS 29 OUT7 (OUT7B) 24 23 21 22 20 19 VS SCLK CS SDO SDIO RESET PD OUT2 OUT2 VS_LVPECL OUT3 OUT3 VS 18 25 17 26 OUT6 (OUT6A) 12 16 27 OUT6 (OUT6B) 11 15 28 OUT7 (OUT7A) 10 14 9 06428-003 8 13 REFMON LD VCP CP STATUS REF_SEL SYNC LF BYPASS VS CLK CLK 46 CPRSET 48 REFIN (REF1) PIN CONFIGURATION AND FUNCTION DESCRIPTIONS NOTES 1. THE EXTERNAL PADDLE ON THE BOTTOM OF THE PACKAGE MUST BE CONNECTED TO GROUND FOR PROPER OPERATION. Figure 6. Pin Configuration Table 20. Pin Function Descriptions Pin No. 1 Input/ Output O Pin Type 3.3 V CMOS Mnemonic REFMON 2 O 3.3 V CMOS LD 3 I Power VCP 4 5 6 O O I 3.3 V CMOS 3.3 V CMOS 3.3 V CMOS CP STATUS REF_SEL 7 I 3.3 V CMOS SYNC 8 I Loop filter LF 9 10, 24, 25, 30, 31, 36, 37, 43, 45 11 O I Loop filter Power BYPASS VS I CLK 12 I 13 14 I I Differential clock input Differential clock input 3.3 V CMOS 3.3 V CMOS CLK SCLK CS Description Reference Monitor (Output). This pin has multiple selectable outputs; see Table 54, Register 0x01B. Lock Detect (Output). This pin has multiple selectable outputs; see Table 54, Register 0x01A. Power Supply for Charge Pump (CP); VS ≤ VCP ≤ 5.0 V. This pin is usually 3.3 V for most applications; but if a 5 V external VCXO is used, this pin should be 5 V. Charge Pump (Output). Connects to external loop filter. Status (Output). This pin has multiple selectable outputs; see Table 54, Register 0x017. Reference Select. Selects REF1 (low) or REF2 (high). This pin has an internal 30 kΩ pull-down resistor. Manual Synchronizations and Manual Holdover. This pin initiates a manual synchronization and is also used for manual holdover. Active low. This pin has an internal 30 kΩ pull-up resistor. Loop Filter (Input). Connects to VCO control voltage node internally. This pin has 31 pF of internal capacitance to ground, which may influence the loop filter design for large loop bandwidths. This pin is for bypassing the LDO to ground with a capacitor. 3.3 V Power Pins. Along with CLK, this is the self-biased differential input for the clock distribution section. This pin can be left floating if internal VCO is used. Along with CLK, this is the self-biased differential input for the clock distribution section. This pin can be left floating if internal VCO is used. Serial Control Port Data Clock Signal. Serial Control Port Chip Select; Active Low. This pin has an internal 30 kΩ pull-up resistor. Rev. E | Page 18 of 80 Data Sheet Pin No. 15 16 Input/ Output O I/O 17 18 21, 40 42 41 39 38 19 20 22 23 35 I I I O O O O O O O O O 34 O 33 O 32 O 26 O 27 O 28 O 29 O 44 O 46 O 47 I 48 I EPAD AD9517-4 Pin Type 3.3 V CMOS 3.3 V CMOS Mnemonic SDO SDIO RSET Description Serial Control Port. Unidirectional serial data output. Serial Control Port. Bidirectional serial data input/output and unidirectional serial data input. Chip Reset, Active Low. This pin has an internal 30 kΩ pull-up resistor. Chip Power Down, Active Low. This pin has an internal 30 kΩ pull-up resistor. Extended Voltage 2.5 V to 3.3 V LVPECL Power Pins. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVPECL Output; One Side of a Differential LVPECL Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. LVDS/CMOS Output; One Side of a Differential LVDS Output or a Single-Ended CMOS Output. Resistor connected here sets internal bias currents. Nominal value = 4.12 kΩ. 3.3 V CMOS 3.3 V CMOS Power LVPECL LVPECL LVPECL LVPECL LVPECL LVPECL LVPECL LVPECL LVDS or CMOS LVDS or CMOS LVDS or CMOS LVDS or CMOS LVDS or CMOS LVDS or CMOS LVDS or CMOS LVDS or CMOS Current set resistor Current set resistor Reference input Reference input GND RESET PD VS_LVPECL OUT0 OUT0 OUT1 OUT1 OUT2 OUT2 OUT3 OUT3 OUT4 (OUT4A) CPRSET Resistor connected here sets CP current range. Nominal value = 5.1 kΩ. REFIN (REF2) Along with REFIN, this is the self-biased differential input for the PLL reference. Alternatively, this pin is a single-ended input for REF2. Along with REFIN, this is the self-biased differential input for the PLL reference. Alternatively, this pin is a single-ended input for REF1. Ground. The external paddle on the bottom of the package must be connected to ground for proper operation. OUT4 (OUT4B) OUT5 (OUT5A) OUT5 (OUT5B) OUT6 (OUT6A) OUT6 (OUT6B) OUT7 (OUT7A) OUT7 (OUT7B) REFIN (REF1) GND Rev. E | Page 19 of 80 AD9517-4 Data Sheet TYPICAL PERFORMANCE CHARACTERISTICS 240 50 2 CHANNELS—4 LVPECL 220 45 40 KVCO (MHz/V) CURRENT (mA) 200 180 2 CHANNELS—2 LVPECL 160 35 30 140 0 1000 500 1500 2500 2000 3000 FREQUENCY (MHz) 20 1.45 06428-007 100 1.55 1.75 VCO FREQUENCY (GHz) Figure 7. Current vs. Frequency, Direct to Output, LVPECL Outputs Figure 10. VCO KVCO vs. Frequency 180 5.0 4.5 2 CHANNELS—4 LVDS CURRENT FROM CP PIN (mA) 160 CURRENT (mA) 1.65 06428-200 25 1 CHANNEL—1 LVPECL 120 140 2 CHANNELS—2 LVDS 120 100 4.0 3.5 PUMP DOWN PUMP UP 3.0 2.5 2.0 1.5 1.0 0.5 1 CHANNEL—1 LVDS 200 400 600 800 FREQUENCY (MHz) 0 1.0 1.5 2.5 2.0 3.0 VOLTAGE ON CP PIN (V) Figure 8. Current vs. Frequency—LVDS Outputs (Includes Clock Distribution Current Draw) Figure 11. Charge Pump Characteristics at VCP = 3.3 V 240 5.0 4.5 CURRENT FROM CP PIN (mA) 220 200 2 CHANNELS—8 CMOS 180 2 CHANNELS—2 CMOS 160 140 120 1 CHANNEL—2 CMOS 100 4.0 3.5 PUMP DOWN PUMP UP 3.0 2.5 2.0 1.5 1.0 0.5 80 0 50 100 150 200 FREQUENCY (MHz) 250 Figure 9. Current vs. Frequency—CMOS Outputs 0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 VOLTAGE ON CP PIN (V) Figure 12. Charge Pump Characteristics at VCP = 5.0 V Rev. E | Page 20 of 80 5.0 06428-012 1 CHANNEL—1 CMOS 06428-009 CURRENT (mA) 0.5 0 06428-011 0 06428-008 80 AD9517-4 –140 10 –145 –10 RELATIVE POWER (dB) 0 –150 –155 –160 –20 –30 –40 –50 –60 –70 –80 –90 –165 –170 0.1 1 10 100 –110 PFD FREQUENCY (MHz) CENTER 122.88MHz 5MHz/DIV SPAN 50MHz 06428-202 –100 06428-013 PFD PHASE NOISE REFERRED TO PFD INPUT (dBc/Hz) Data Sheet Figure 16. PFD/CP Spurs; 122.88 MHz; PFD = 15.36 MHz; LBW = 135 kHz; ICP = 3 mA; fVCO = 1.475 GHz Figure 13. PFD Phase Noise Referred to PFD Input vs. PFD Frequency –210 10 –212 –10 RELATIVE POWER (dB) PLL FIGURE OF MERIT (dBc/Hz) 0 –214 –216 –218 –220 –20 –30 –40 –50 –60 –70 –80 –90 –222 0 0.5 1.0 2.5 2.0 1.5 SLEW RATE (V/ns) –110 06428-136 –224 CENTER 122.88MHz 100kHz/DIV SPAN 1MHz 06428-203 –100 Figure 17. Output Spectrum, LVPECL; 122.88 MHz; PFD = 15.36 MHz; LBW = 135 kHz; ICP = 3 mA; fVCO = 1.475 GHz Figure 14. PLL Figure of Merit (FOM) vs. Slew Rate at REFIN/REFIN 2.1 10 1.9 –10 RELATIVE POWER (dB) 1.7 1.5 1.3 –20 –30 –40 –50 –60 –70 –80 –90 1.1 0.9 1.45 1.50 1.55 1.60 1.65 1.70 1.75 1.80 FREQUENCY (GHz) –110 CENTER 122.88MHz 100kHz/DIV SPAN 1MHz 06428-204 –100 06428-201 VCO TUNING VOLTAGE (V) 0 Figure 18. Output Spectrum, LVDS; 122.88 MHz; PFD = 15.36 MHz; LBW = 135 kHz; ICP = 3 mA; fVCO = 1.475 GHz Figure 15. VCO Tuning Voltage vs. Frequency (Note that VCO calibration centers the dc tuning voltage for the PLL setup that is active during calibration.) Rev. E | Page 21 of 80 AD9517-4 Data Sheet 0.4 0.6 DIFFERENTIAL OUTPUT (V) DIFFERENTIAL OUTPUT (V) 1.0 0.2 –0.2 0.2 0 –0.2 –0.6 5 15 10 20 25 TIME (ns) –0.4 1 0 06428-017 0 06428-014 –1.0 2 TIME (ns) Figure 19. LVPECL Output (Differential) at 100 MHz Figure 22. LVDS Output (Differential) at 800 MHz 1.0 OUTPUT (V) DIFFERENTIAL OUTPUT (V) 2.8 0.6 0.2 –0.2 1.8 0.8 0 1 2 TIME (ns) 06428-015 –0.2 –1.0 0 20 40 60 80 100 TIME (ns) Figure 20. LVPECL Output (Differential) at 1600 MHz 06428-018 –0.6 Figure 23. CMOS Output at 25 MHz 0.4 OUTPUT (V) 0.2 0 1.8 0.8 –0.2 –0.4 0 5 10 15 20 TIME (ns) 25 Figure 21. LVDS Output (Differential) at 100 MHz 0 2 4 6 8 TIME (ns) Figure 24. CMOS Output at 250 MHz Rev. E | Page 22 of 80 10 12 06428-019 –0.2 06428-016 DIFFERENTIAL OUTPUT (V) 2.8 Data Sheet AD9517-4 1600 –80 1400 PHASE NOISE (dBc/Hz) DIFFERENTIAL SWING (mV p-p) –90 1200 1000 –100 –110 –120 –130 0 2 1 3 FREQUENCY (GHz) –150 10k 06428-020 800 Figure 25. LVPECL Differential Swing vs. Frequency Using a Differential Probe Across the Output Pair 100k 1M 10M 100M FREQUENCY (Hz) 06428-205 –140 Figure 28. Internal VCO Phase Noise (Absolute) Direct to LVPECL at 1800 MHz –80 –90 PHASE NOISE (dBc/Hz) DIFFERENTIAL SWING (mV p-p) 700 600 –100 –110 –120 –130 0 100 200 300 400 500 600 700 800 FREQUENCY (MHz) –150 10k 06428-021 500 Figure 26. LVDS Differential Swing vs. Frequency Using a Differential Probe Across the Output Pair 1M 10M 100M FREQUENCY (Hz) Figure 29. Internal VCO Phase Noise (Absolute) Direct to LVPECL at 1625 MHz –80 CL = 2pF 3 –90 CL = 10pF PHASE NOISE (dBc/Hz) OUTPUT SWING (V) 10k 06428-206 –140 2 CL = 20pF 1 –100 –110 –120 –130 0 100 200 300 400 500 600 OUTPUT FREQUENCY (MHz) Figure 27. CMOS Output Swing vs. Frequency and Capacitive Load –150 10k 100k 1M FREQUENCY (Hz) 10M 100M 06428-207 0 06428-133 –140 Figure 30. Internal VCO Phase Noise (Absolute) Direct to LVPECL at 1450 MHz Rev. E | Page 23 of 80 AD9517-4 Data Sheet –120 –110 –125 PHASE NOISE (dBc/Hz) PHASE NOISE (dBc/Hz) –120 –130 –135 –140 –145 –150 –130 –140 –150 100 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) –160 10 06428-026 –120 –110 PHASE NOISE (dBc/Hz) 1k 10k 100k 1M 10M 100M 10M 100M –120 –130 –150 10 06428-027 100 FREQUENCY (Hz) 100 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) Figure 35. Phase Noise (Additive) LVDS at 800 MHz, Divide-by-2 Figure 32. Phase Noise (Additive) LVPECL at 200 MHz, Divide-by-5 –120 –110 –130 PHASE NOISE (dBc/Hz) –100 –120 –130 –140 –150 –160 –140 100 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) 06428-128 PHASE NOISE (dBc/Hz) 1M –140 –150 –150 10 100k 06428-130 PHASE NOISE (dBc/Hz) –100 –160 10 10k Figure 34. Phase Noise (Additive) LVDS at 200 MHz, Divide-by-1 –110 –140 1k FREQUENCY (Hz) Figure 31. Phase Noise (Additive) LVPECL at 245.76 MHz, Divide-by-1 –130 100 –170 10 100 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) Figure 36. Phase Noise (Additive) CMOS at 50 MHz, Divide-by-20 Figure 33. Phase Noise (Additive) LVPECL at 1600 MHz, Divide-by-1 Rev. E | Page 24 of 80 06428-131 –160 10 06428-142 –155 Data Sheet AD9517-4 –100 –120 PHASE NOISE (dBc/Hz) PHASE NOISE (dBc/Hz) –110 –120 –130 –140 –130 –140 –150 100 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) –160 1k 06428-132 –160 10 Figure 37. Phase Noise (Additive) CMOS at 250 MHz, Divide-by-4 10k 100k 1M 10M 100M FREQUENCY (Hz) 06428-140 –150 Figure 40. Phase Noise (Absolute), External VCXO (Toyocom TCO-2112) at 245.76 MHz; PFD = 15.36 MHz; LBW = 250 Hz; LVPECL Output = 245.76 MHz 1000 –120 –140 –150 –160 1k 10k 100k 1M 10M 100M FREQUENCY (Hz) Figure 38. Phase Noise (Absolute) Clock Generation; Internal VCO at 1.475 GHz; PFD = 15.36 MHz; LBW = 135 kHz; LVPECL Output = 122.88 MHz –90 PHASE NOISE (dBc/Hz) –100 –110 –120 –130 –140 –160 1k 10k 100k 1M FREQUENCY (Hz) 10M 100M 06428-209 –150 Figure 39. Phase Noise (Absolute) Clock Cleanup; Internal VCO at 1.556 GHz; PFD = 19.44 MHz; LBW = 12.8 kHz; LVPECL Output = 155.52 MHz Rev. E | Page 25 of 80 100 fOBJ 10 1 NOTE: 375UI MAX AT 10Hz OFFSET IS THE MAXIMUM JITTER THAT CAN BE GENERATED BY THE TEST EQUIPMENT. FAILURE POINT IS GREATER THAN 375UI. 0.1 0.01 0.1 1 10 100 JITTER FREQUENCY (kHz) Figure 41. GR-253 Jitter Tolerance Plot 1000 06427-148 INPUT JITTER AMPLITUDE (UI p-p) –130 06428-208 PHASE NOISE (dBc/Hz) OC-48 OBJECTIVE MASK AD9517 AD9517-4 Data Sheet TERMINOLOGY Phase Jitter and Phase Noise An ideal sine wave can be thought of as having a continuous and even progression of phase with time from 0° to 360° for each cycle. Actual signals, however, display a certain amount of variation from ideal phase progression over time. This phenomenon is called phase jitter. Although many causes can contribute to phase jitter, one major cause is random noise, which is characterized statistically as being Gaussian (normal) in distribution. This phase jitter leads to a spreading out of the energy of the sine wave in the frequency domain, producing a continuous power spectrum. This power spectrum is usually reported as a series of values whose units are dBc/Hz at a given offset in frequency from the sine wave (carrier). The value is a ratio (expressed in dB) of the power contained within a 1 Hz bandwidth with respect to the power at the carrier frequency. For each measurement, the offset from the carrier frequency is also given. It is meaningful to integrate the total power contained within some interval of offset frequencies (for example, 10 kHz to 10 MHz). This is called the integrated phase noise over that frequency offset interval and can be readily related to the time jitter due to the phase noise within that offset frequency interval. Phase noise has a detrimental effect on the performance of ADCs, DACs, and RF mixers. It lowers the achievable dynamic range of the converters and mixers, although they are affected in somewhat different ways. Time Jitter Phase noise is a frequency domain phenomenon. In the time domain, the same effect is exhibited as time jitter. When observing a sine wave, the time of successive zero crossings varies. In a square wave, the time jitter is a displacement of the edges from their ideal (regular) times of occurrence. In both cases, the variations in timing from the ideal are the time jitter. Because these variations are random in nature, the time jitter is specified in units of seconds root mean square (rms) or 1 sigma of the Gaussian distribution. Time jitter that occurs on a sampling clock for a DAC or an ADC decreases the signal-to-noise ratio (SNR) and dynamic range of the converter. A sampling clock with the lowest possible jitter provides the highest performance from a given converter. Additive Phase Noise Additive phase noise is the amount of phase noise that can be attributed to the device or subsystem being measured. The phase noise of any external oscillators or clock sources is subtracted. This makes it possible to predict the degree to which the device impacts the total system phase noise when used in conjunction with the various oscillators and clock sources, each of which contributes its own phase noise to the total. In many cases, the phase noise of one element dominates the system phase noise. When there are multiple contributors to phase noise, the total is the square root of the sum of squares of the individual contributors. Additive Time Jitter Additive time jitter is the amount of time jitter that can be attributed to the device or subsystem being measured. The time jitter of any external oscillators or clock sources is subtracted. This makes it possible to predict the degree to which the device impacts the total system time jitter when used in conjunction with the various oscillators and clock sources, each of which contributes its own time jitter to the total. In many cases, the time jitter of the external oscillators and clock sources dominates the system time jitter. Rev. E | Page 26 of 80 Data Sheet AD9517-4 DETAILED BLOCK DIAGRAM REF_ SEL VS GND RSET REFMON CPRSET VCP DISTRIBUTION REFERENCE REFERENCE SWITCHOVER LD REF1 STATUS REF2 R DIVIDER STATUS REFIN (REF1) PROGRAMMABLE R DELAY VCO STATUS REFIN (REF2) BYPASS PLL REFERENCE LOCK DETECT LOW DROPOUT REGULATOR (LDO) P, P + 1 PRESCALER A/B COUNTERS PROGRAMMABLE N DELAY PHASE FREQUENCY DETECTOR HOLD CHARGE PUMP CP N DIVIDER LF VCO STATUS DIVIDE BY 2, 3, 4, 5, OR 6 CLK CLK 1 0 OUT0 DIVIDE BY 1 TO 32 PD SYNC OUT0 LVPECL OUT1 DIGITAL LOGIC OUT1 RESET OUT2 DIVIDE BY 1 TO 32 OUT3 SERIAL CONTROL PORT OUT3 OUT4 (OUT4A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 OUT4 (OUT4B) LVDS/CMOS OUT5 (OUT5A) ∆T OUT5 (OUT5B) OUT6 (OUT6A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 LVDS/CMOS ∆T AD9517-4 Figure 42. Detailed Block Diagram Rev. E | Page 27 of 80 OUT6 (OUT6B) OUT7 (OUT7A) OUT7 (OUT7B) 06428-002 SCLK SDIO SDO CS OUT2 LVPECL AD9517-4 Data Sheet THEORY OF OPERATION OPERATIONAL CONFIGURATIONS Table 21. Default Settings of Some PLL Registers The AD9517 can be configured in several ways. These configurations must be set up by loading the control registers (see Table 52 and Table 53 through Table 62). Each section or function must be individually programmed by setting the appropriate bits in the corresponding control register or registers. Register 0x010[1:0] = 01b 0x1E0[2:0] = 010b 0x1E1[0] = 0b 0x1E1[1] = 0b High Frequency Clock Distribution—CLK or External VCO > 1600 MHz When using the internal PLL with an external VCO, the PLL must be turned on. The AD9517 power-up default configuration has the PLL powered off and the routing of the input set so that the CLK/CLK input is connected to the distribution section through the VCO divider (divide-by-2/ divide-by-3/divide-by-4/ divide-by-5/divide-by-6). This is a distribution-only mode that allows for an external input up to 2400 MHz (see Table 3). The maximum frequency that can be applied to the channel dividers is 1600 MHz; therefore, higher input frequencies must be divided down before reaching the channel dividers. This input routing can also be used for lower input frequencies, but the minimum divide is 2 before the channel dividers. When the PLL is enabled, this routing also allows the use of the PLL with an external VCO or VCXO with a frequency of less than 2400 MHz. In this configuration, the internal VCO is not used and is powered off. The external VCO/VCXO feeds directly into the prescaler. The register settings shown in Table 21 are the default values of these registers at power-up or after a reset operation. If the contents of the registers are altered by prior programming after power-up or reset, these registers can also be set intentionally to these values. Function PLL asynchronous power-down (PLL off ). Set VCO divider = 4. Use the VCO divider. CLK selected as the source. Table 22. Settings When Using an External VCO Register 0x010[1:0] = 00b 0x010 to 0x01D 0x1E1[1] = 0b Function PLL normal operation (PLL on). PLL settings. Select and enable a reference input; set R, N (P, A, B), PFD polarity, and ICP, according to the intended loop configuration. CLK selected as the source An external VCO requires an external loop filter that must be connected between CP and the tuning pin of the VCO. This loop filter determines the loop bandwidth and stability of the PLL. Make sure to select the proper PFD polarity for the VCO being used. Table 23. Setting the PFD Polarity Register 0x010[7] = 0b 0x010[7] = 1b After the appropriate register values are programmed, Register 0x232 must be set to 0x01 for the values to take effect. Rev. E | Page 28 of 80 Function PFD polarity positive (higher control voltage produces higher frequency). PFD polarity negative (higher control voltage produces lower frequency). Data Sheet AD9517-4 REF_ SEL VS GND RSET REFMON CPRSET VCP DISTRIBUTION REFERENCE REFERENCE SWITCHOVER LD REF1 STATUS REF2 R DIVIDER STATUS REFIN (REF1) PROGRAMMABLE R DELAY VCO STATUS REFIN (REF2) BYPASS PLL REFERENCE LOCK DETECT LOW DROPOUT REGULATOR (LDO) P, P + 1 PRESCALER A/B COUNTERS PROGRAMMABLE N DELAY PHASE FREQUENCY DETECTOR HOLD CHARGE PUMP CP N DIVIDER LF VCO STATUS DIVIDE BY 2, 3, 4, 5, OR 6 CLK CLK 1 0 OUT0 DIVIDE BY 1 TO 32 PD SYNC OUT0 LVPECL OUT1 DIGITAL LOGIC OUT1 RESET OUT2 DIVIDE BY 1 TO 32 OUT3 SERIAL CONTROL PORT OUT3 OUT4 (OUT4A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 OUT4 (OUT4B) LVDS/CMOS OUT5 (OUT5A) ∆T OUT5 (OUT5B) OUT6 (OUT6A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 LVDS/CMOS ∆T AD9517-4 Figure 43. High Frequency Clock Distribution or External VCO > 1600 MHz Rev. E | Page 29 of 80 OUT6 (OUT6B) OUT7 (OUT7A) OUT7 (OUT7B) 06428-029 SCLK SDIO SDO CS OUT2 LVPECL AD9517-4 Data Sheet REF_ SEL VS GND RSET REFMON CPRSET VCP DISTRIBUTION REFERENCE REFERENCE SWITCHOVER LD REF1 STATUS REF2 R DIVIDER STATUS REFIN (REF1) PROGRAMMABLE R DELAY VCO STATUS REFIN (REF2) BYPASS PLL REFERENCE LOCK DETECT LOW DROPOUT REGULATOR (LDO) P, P + 1 PRESCALER PROGRAMMABLE N DELAY A/B COUNTERS PHASE FREQUENCY DETECTOR HOLD CHARGE PUMP CP N DIVIDER LF VCO STATUS DIVIDE BY 2, 3, 4, 5, OR 6 CLK CLK 1 0 OUT0 DIVIDE BY 1 TO 32 PD SYNC OUT0 LVPECL OUT1 DIGITAL LOGIC OUT1 RESET OUT2 DIVIDE BY 1 TO 32 OUT3 SERIAL CONTROL PORT OUT3 OUT4 (OUT4A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 OUT4 (OUT4B) LVDS/CMOS OUT5 (OUT5A) ∆T OUT5 (OUT5B) OUT6 (OUT6A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 LVDS/CMOS ∆T AD9517-4 OUT6 (OUT6B) OUT7 (OUT7A) OUT7 (OUT7B) 06428-030 SCLK SDIO SDO CS OUT2 LVPECL Figure 44. Internal VCO and Clock Distribution Internal VCO and Clock Distribution Table 24. Settings When Using Internal VCO When using the internal VCO and PLL, the VCO divider must be employed to ensure that the frequency presented to the channel dividers does not exceed their specified maximum frequency of 1600 MHz (see Table 3). The internal PLL uses an external loop filter to set the loop bandwidth. The external loop filter is also crucial to the loop stability. Register 0x010[1:0] = 00b 0x010 to 0x01D When using the internal VCO, it is necessary to calibrate the VCO (Register 0x018[0]) to ensure optimal performance. For internal VCO and clock distribution applications, use the register settings that are shown in Table 24. 0x018[0] = 0b, 0x232[0] = 1b 0x1E0[2:0] 0x1E1[0] = 0b 0x1E1[1] = 1b 0x018[0] = 1b, 0x232[0] = 1b Rev. E | Page 30 of 80 Function PLL normal operation (PLL on). PLL settings. Select and enable a reference input; set R, N (P, A, B), PFD polarity, and ICP according to the intended loop configuration. Reset VCO calibration. This is not required the first time after power-up, but it must be performed subsequently. Set VCO divider to divide-by-2, divide-by-3, divide-by-4, divide-by-5, and divide-by-6. Use the VCO divider as the source for the distribution section. Select VCO as the source. Initiate VCO calibration. Data Sheet AD9517-4 REF_ SEL VS GND RSET REFMON CPRSET VCP DISTRIBUTION REFERENCE REFERENCE SWITCHOVER LD REF1 STATUS REF2 R DIVIDER STATUS REFIN (REF1) PROGRAMMABLE R DELAY VCO STATUS REFIN (REF2) BYPASS PLL REFERENCE LOCK DETECT LOW DROPOUT REGULATOR (LDO) P, P + 1 PRESCALER A/B COUNTERS PROGRAMMABLE N DELAY PHASE FREQUENCY DETECTOR HOLD CHARGE PUMP CP N DIVIDER LF VCO STATUS DIVIDE BY 2, 3, 4, 5, OR 6 CLK CLK 1 0 OUT0 DIVIDE BY 1 TO 32 PD SYNC OUT0 LVPECL OUT1 DIGITAL LOGIC OUT1 RESET OUT2 DIVIDE BY 1 TO 32 OUT3 SERIAL CONTROL PORT OUT3 OUT4 (OUT4A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 OUT4 (OUT4B) LVDS/CMOS OUT5 (OUT5A) ∆T OUT5 (OUT5B) OUT6 (OUT6A) ∆T DIVIDE BY 1 TO 32 DIVIDE BY 1 TO 32 LVDS/CMOS ∆T AD9517-4 Figure 45. Clock Distribution or External VCO < 1600 MHz Rev. E | Page 31 of 80 OUT6 (OUT6B) OUT7 (OUT7A) OUT7 (OUT7B) 06428-028 SCLK SDIO SDO CS OUT2 LVPECL AD9517-4 Data Sheet Clock Distribution or External VCO < 1600 MHz When the external clock source to be distributed or the external VCO/VCXO is less than 1600 MHz, a configuration that bypasses the VCO divider can be used. This configuration differs from the High Frequency Clock Distribution—CLK or External VCO > 1600 MHz section only in that the VCO divider (divide-by-2, divide-by-3, divide-by-4, divide-by-5, and divide-by-6) is bypassed. This limits the frequency of the clock source to <1600 MHz (due to the maximum input frequency allowed at the channel dividers). When using the internal PLL with an external VCO of <1600 MHz, the PLL must be turned on. Table 26. Settings for Using Internal PLL with External VCO < 1600 MHz Register 0x1E1[0] = 1b 0x010[1:0] = 00b Configuration and Register Settings For clock distribution applications where the external clock is <1600 MHz, use the register settings that are shown in Table 25. Table 25. Settings for Clock Distribution < 1600 MHz Register 0x010[1:0] = 01b 0x1E1[0] = 1b 0x1E1[1] = 0b Function PLL asynchronous power-down (PLL off ) Bypass the VCO divider as source for distribution section CLK selected as the source Function Bypass the VCO divider as source for distribution section PLL normal operation (PLL on), along with other appropriate PLL settings in Register 0x010 to Register 0x01D An external VCO/VCXO requires an external loop filter that must be connected between CP and the tuning pin of the VCO/VCXO. This loop filter determines the loop bandwidth and stability of the PLL. Make sure to select the proper PFD polarity for the VCO/VCXO being used. Table 27. Setting the PFD Polarity Register 0x010[7] = 0b 0x010[7] = 1b Function PFD polarity positive (higher control voltage produces higher frequency) PFD polarity negative (higher control voltage produces lower frequency) After the appropriate register values are programmed, Register 0x232 must be set to 0x01 for the values to take effect. Rev. E | Page 32 of 80 Data Sheet AD9517-4 Phase-Locked Loop (PLL) REF_SEL VS GND RSET REFMON CPRSET VCP DIST REF REFERENCE SWITCHOVER LD LOCK DETECT REF1 STATUS REF2 PROGRAMMABLE R DELAY R DIVIDER STATUS PLL REF HOLD REFIN (REF1) REFIN (REF2) BYPASS N DIVIDER LOW DROPOUT REGULATOR (LDO) P, P + 1 PRESCALER A/B COUNTERS PROGRAMMABLE N DELAY PHASE FREQUENCY DETECTOR CHARGE PUMP CP VCO STATUS LF STATUS DIVIDE BY 2, 3, 4, 5, OR 6 CLK 0 1 CLK 1 06428-064 VCO 0 Figure 46. PLL Functional Blocks The AD9517 includes an on-chip PLL with an on-chip VCO. The PLL blocks can be used either with the on-chip VCO to create a complete phase-locked loop, or with an external VCO or VCXO. The PLL requires an external loop filter, which usually consists of a small number of capacitors and resistors. The configuration and components of the loop filter help to establish the loop bandwidth and stability of the operating PLL. These are managed through programmable register settings (see Table 52 and Table 54) and by the design of the external loop filter. Successful PLL operation and satisfactory PLL loop performance are highly dependent upon proper configuration of the PLL settings. The design of the external loop filter is crucial to the proper operation of the PLL. A thorough knowledge of PLL theory and design is helpful. The AD9517 PLL is useful for generating clock frequencies from a supplied reference frequency. This includes conversion of reference frequencies to much higher frequencies for subsequent division and distribution. In addition, the PLL can be exploited to clean up jitter and phase noise on a noisy reference. The exact choices of PLL parameters and loop dynamics are very application specific. The flexibility and depth of the AD9517 PLL allow the part to be tailored to function in many different applications and signal environments. ADIsimCLK™ (V1.2 or later) is a free program that can help with the design and exploration of the capabilities and features of the AD9517, including the design of the PLL loop filter. It is available at www.analog.com/clocks. Configuration of the PLL The AD9517 allows flexible configuration of the PLL, accommodating various reference frequencies, PFD comparison frequencies, VCO frequencies, internal or external VCO/VCXO, and loop dynamics. This is accomplished by the various settings that include the R divider, the N divider, the PFD polarity (only applicable to external VCO/VCXO), the antibacklash pulse width, the charge pump current, the selection of internal VCO or external VCO/VCXO, and the loop bandwidth. Phase Frequency Detector (PFD) The PFD takes inputs from the R counter and N counter and produces an output proportional to the phase and frequency difference between them. The PFD includes a programmable delay element that controls the width of the antibacklash pulse. This pulse ensures that there is no dead zone in the PFD transfer function and minimizes phase noise and reference spurs. The antibacklash pulse width is set by Register 0x017[1:0]. An important limit to keep in mind is the maximum frequency allowed into the PFD, which in turn determines the correct antibacklash pulse setting. The antibacklash pulse setting is specified in the phase/frequency detector parameter of Table 2. Rev. E | Page 33 of 80 AD9517-4 Data Sheet The charge pump is controlled by the PFD. The PFD monitors the phase and frequency relationship between its two inputs, and tells the CP to pump up or pump down to charge or discharge the integrating node (part of the loop filter). The integrated and filtered CP current is transformed into a voltage that drives the tuning node of the internal VCO through the LF pin (or the tuning pin of an external VCO) to move the VCO frequency up or down. The CP can be set (Register 0x010[6:4]) for high impedance (allows holdover operation), for normal operation (attempts to lock the PLL loop), for pump up, or for pump down (test modes). The CP current is programmable in eight steps from (nominally) 600 µA to 4.8 mA. The exact value of the CP current LSB is set by the CPRSET resistor, which is nominally 5.1 kΩ. If the value of the resistor connected to the CP_RSET pin is doubled, the resulting charge pump current range becomes 300 µA to 2.4 mA. When using an external VCO, the external loop filter should be referenced to ground. See Figure 48 for an example of an external loop filter for a PLL using an external VCO. AD9517-4 VCO LF 31pF R2 CP R1 CHARGE PUMP BYPASS C1 Figure 47. Example of External Loop Filter for a PLL Using the Internal VCO AD9517-4 EXTERNAL VCO/VCXO CLK/CLK R2 CP The on-chip VCO is powered by an on-chip, low dropout (LDO), linear voltage regulator. The LDO provides some isolation of the VCO from variations in the power supply voltage level. The BYPASS pin should be connected to ground by a 220 nF capacitor to ensure stability. This LDO employs the same technology used in the anyCAP® line of regulators from Analog Devices, Inc., making it insensitive to the type of capacitor used. Driving an external load from the BYPASS pin is not supported. Note that the reference input signal must be present and the VCO divider must not be static during VCO calibration. PLL External Loop Filter When using the internal VCO, the external loop filter should be referenced to the BYPASS pin for optimal noise and spurious performance. An example of an external loop filter for a PLL that uses the internal VCO is shown in Figure 47. The thirdorder design shown in Figure 47 usually offers best performance. A loop filter must be calculated for each desired PLL configuration. The values of the components depend upon the VCO frequency, the KVCO, the PFD frequency, the CP current, the desired loop bandwidth, and the desired phase margin. The loop filter affects the phase noise, loop settling time, and loop stability. A basic knowledge of PLL theory is helpful for understanding loop filter design. ADIsimCLK can help with the calculation of a loop filter according to the application requirements. C3 CBP = 220nF On-Chip VCO CHARGE PUMP R1 C1 C2 C3 06428-265 The AD9517 includes an on-chip VCO covering the frequency range shown in Table 2.. The calibration procedure ensures that the VCO operating voltage is centered for the desired VCO frequency. The VCO must be calibrated when the VCO loop is first set up, as well as any time the nominal VCO frequency changes. However, once the VCO is calibrated, the VCO has sufficient operating range to stay locked over temperature and voltage extremes without needing additional calibration. See the VCO Calibration section for additional information. C2 06428-065 Charge Pump (CP) Figure 48. Example of External Loop Filter for a PLL Using an External VCO PLL Reference Inputs The AD9517 features a flexible PLL reference input circuit that allows either a fully differential input or two separate single-ended inputs. The input frequency range for the reference inputs is specified in Table 2. Both the differential and the single-ended inputs are self-biased, allowing for easy ac coupling of input signals. The differential input and the single-ended inputs share the two pins, REFIN and REFIN (REF1 and REF2, respectively). The desired reference input type is selected and controlled by Register 0x01C (see Table 52 and Table 54). When the differential reference input is selected, the self-bias level of the two sides is offset slightly (~100 mV, see Table 2) to prevent chattering of the input buffer when the reference is slow or missing. This increases the voltage swing that is required of the driver and overcomes the offset. The differential reference input can be driven by either ac-coupled LVDS or ac-coupled LVPECL signals. The single-ended inputs can be driven by either a dc-coupled CMOS level signal or an ac-coupled sine-wave or square wave. Each single-ended input can be independently powered down when not needed to increase isolation and reduce power. Either a differential or a single-ended reference must be specifically enabled. All PLL reference inputs are off by default. The differential reference input is powered down whenever the PLL is powered down, or when the differential reference input is not selected. The single-ended buffers power down when the PLL is powered down, and when their individual power down registers are set. When the differential mode is selected, the single-ended inputs are powered down. Rev. E | Page 34 of 80 Data Sheet AD9517-4 In differential mode, the reference input pins are internally selfbiased so that they can be ac-coupled via capacitors. It is possible to dc couple to these inputs. If the differential REFIN is driven by a single-ended signal, the unused side (REFIN) should be decoupled via a suitable capacitor to a quiet ground. Figure 49 shows the equivalent circuit of REFIN. VS Automatic revertive switchover relies on the REFMON pin to indicate when REF1 disappears. By programming Register 0x01B = 0xF7 and Register 0x01C = 0x26, the REFMON pin is programmed to be high when REF1 is invalid, which commands the switch to REF2. When REF1 is valid again, the REFMON pin goes low, and the part again locks to REF1. It is also possible to use the STATUS pin for this function, and REF2 can be used as the preferred reference. A switchover deglitch feature ensures that the PLL does not receive rising edges that are far out of alignment with the newly selected reference. 85kΩ REF1 Automatic nonrevertive switching is not supported. Reference Divider R VS 10kΩ The reference inputs are routed to the reference divider, R. R (a 14-bit counter) can be set to any value from 0 to 16383 by writing to Register 0x011 and Register 0x012. (Both R = 0 and R = 1 give divide-by-1.) The output of the R divider goes to one of the PFD inputs to be compared to the VCO frequency divided by the N divider. The frequency applied to the PFD must not exceed the maximum allowable frequency, which depends on the antibacklash pulse setting (see Table 2). 12kΩ REFIN 150Ω REFIN 150Ω 10kΩ 10kΩ VS REF2 The R counter has its own reset. R counter can be reset using the shared reset bit of the R, A, and B counters. It can also be reset by a SYNC operation. 06428-066 85kΩ VCXO/VCO Feedback Divider N—P, A, B, R The N divider is a combination of a prescaler (P) and two counters, A and B. The total divider value is Figure 49. REFIN Equivalent Circuit Reference Switchover The AD9517 supports dual single-ended CMOS inputs, as well as a single differential reference input. In the dual single-ended reference mode, the AD9517 supports automatic and manual PLL reference clock switching between REF1 (on Pin REFIN) and REF2 (on Pin REFIN). This feature supports networking and other applications that require smooth switching of redundant references. When used in conjunction with the automatic holdover function, the AD9517 can achieve a worst-case reference input switchover with an output frequency disturbance as low as 10 ppm. When using reference switchover, the single-ended reference inputs should be dc-coupled CMOS levels and never be allowed to go to high impedance. If these inputs are allowed to go to high impedance, noise may cause the buffer to chatter, causing a false detection of the presence of a reference. Reference switchover can be performed manually or automatically. Manual switchover is performed either through Register 0x01C or by using the REF_SEL pin. Manual switchover requires the presence of a clock on the reference input that is being switched to, or that the deglitching feature be disabled (Register 0x01C[7]). The reference switching logic fails if this condition is not met, and the PLL does not reacquire. N = (P × B) + A where the value of P can be 2, 4, 8, 16, or 32. Prescaler The prescaler of the AD9517 allows for two modes of operation: a fixed divide (FD) mode of 1, 2, or 3, and dual modulus (DM) mode where the prescaler divides by P and (P + 1) {2 and 3, 4 and 5, 8 and 9, 16 and 17, or 32 and 33}. The prescaler modes of operation are given in Table 54, Register 0x016[2:0]. Not all modes are available at all frequencies (see Table 2). When operating the AD9517 in dual modulus mode (P//P + 1), the equation used to relate input reference frequency to VCO output frequency is fVCO = (fREF/R) × (P × B + A) = fREF × N/R However, when operating the prescaler in an FD mode of 1, 2, or 3, the A counter is not used (A = 0) and the equation simplifies to fVCO = (fREF/R) × (P × B) = fREF × N/R When A = 0, the divide is a fixed divide of P = 2, 4, 8, 16, or 32, in which case the previous equation also applies. Rev. E | Page 35 of 80 AD9517-4 Data Sheet By using combinations of the DM and FD modes, the AD9517 can achieve values of N all the way down to N = 1 and up to N = 26,2175. Table 28 shows how a 10 MHz reference input can be locked to any integer multiple of N. Note that the same value of N can be derived in different ways, as illustrated by the case of N = 12. The user can choose a fixed divide mode of P = 2 with B = 6; use the dual modulus mode of 2/3 with A = 0, B = 6; or use the dual modulus mode of 4/5 with A = 0, B = 3. The maximum frequency into the prescaler in 2/3 dual-modulus mode is limited to 200 MHz. There are only two cases where this frequency limitation limits the flexibility of that N divider: N = 7 and N = 11. In these two cases, the maximum frequency into the prescaler is 300 MHz and is achieved by using the P = 1 FD mode. In all other cases, the user can achieve the desired N divider value by using the other prescaler modes. A and B Counters The B counter must be ≥3 or bypassed, and, unlike the R counter, A = 0 is actually zero. When the prescaler is in dual-modulus mode, the A counter must be less than the B counter. The maximum input frequency to the A/B counter is reflected in the maximum prescaler output frequency (~300 MHz) that is specified in Table 2. This is the prescaler input frequency (VCO or CLK) divided by P. For example, a dual modulus mode of P = 8/9 is not allowed if the VCO frequency is greater than 2400 MHz because the frequency going to the A/B counter is too high. When the AD9517 B counter is bypassed (B = 1), the A counter should be set to 0, and the overall resulting divide is equal to the prescaler setting, P. The possible divide ratios in this mode are 1, 2, 3, 4, 8, 16, and 32. This mode is useful only when an external VCO/VCXO is used because the frequency range of the internal VCO requires an overall feedback divider greater than 32. Although manual reset is not normally required, the A/B counters have their own reset bit. Alternatively, the A and B counters can be reset using the shared reset bit of the R, A, and B counters. Note that these reset bits are not self-clearing. R, A, and B Counters—SYNC Pin Reset The R, A, and B counters can also be reset simultaneously through the SYNC pin. This function is controlled by Register 0x019[7:6] (see Table 54). The SYNC pin reset is disabled by default. R and N Divider Delays Both the R and N dividers feature a programmable delay cell. These delays can be enabled to allow adjustment of the phase relationship between the PLL reference clock and the VCO or CLK. Each delay is controlled by three bits. The total delay range is about 1 ns. See Register 0x019 in Table 54. Table 28. Using a 10 MHz Reference Input to Generate Different VCO Frequencies fREF (MHz) 10 10 10 10 10 10 10 10 R 1 1 1 1 1 1 1 1 P 1 2 1 1 1 2 2 2 A X X X X X X 0 1 B 1 1 3 4 5 3 3 3 N 1 2 3 4 5 6 6 7 fVCO (MHz) 10 20 30 40 50 60 60 70 Mode FD FD FD FD FD FD DM DM 10 10 10 10 10 10 10 10 1 1 1 1 1 10 1 1 2 2 8 8 16 32 8 16 2 1 6 7 7 6 0 14 3 4 18 18 9 47 25 16 8 9 150 151 151 1510 200 270 80 90 1500 1510 1510 1510 2000 2700 DM DM DM DM DM DM DM DM 10 10 32 22 84 2710 2710 DM Comments/Conditions P = 1, B = 1 (A and B counters are bypassed). P = 2, B = 1 (A and B counters are bypassed). A counter is bypassed. A counter is bypassed. A counter is bypassed. A counter is bypassed. Maximum frequency into prescaler in P = 2/3 mode is 200 MHz. If N = 7 or N = 11 is desired for prescaler input frequency of 200 MHz to 300 MHz, use P = 1, and N = 7 or 11, respectively. P = 8 is not allowed (2700 ÷ 8 > 300 MHz). P = 32 is not allowed (A > B not allowed). P = 32, A = 22, B = 84. P = 16 is also permitted. Rev. E | Page 36 of 80 Data Sheet AD9517-4 By selecting the proper output through the mux on each pin, the DLD function can be made available at the LD, STATUS, and REFMON pins. The DLD circuit indicates a lock when the time difference of the rising edges at the PFD inputs is less than a specified value (the lock threshold). The loss of a lock is indicated when the time difference exceeds a specified value (the unlock threshold). Note that the unlock threshold is wider than the lock threshold, which allows some phase error in excess of the lock window to occur without chattering on the lock indicator. The lock detect window timing depends on three settings: the digital lock detect window bit (Register 0x018[4]), the antibacklash pulse width setting (Register 0x017[1:0], see Table 2), and the lock detect counter (Register 0x018[6:5]). A lock is not indicated until there is a programmable number of consecutive PFD cycles with a time difference that is less than the lock detect threshold. The lock detect circuit continues to indicate a lock until a time difference greater than the unlock threshold occurs on a single subsequent cycle. For the lock detect to work properly, the period of the PFD frequency must be greater than the unlock threshold. The number of consecutive PFD cycles required for lock is programmable (Register 0x018[6:5]). when it is selected as the output from the LD pin control (Register 0x01A[5:0]). The current source lock detect provides a current of 110 µA when DLD is true, and it shorts to ground when DLD is false. If a capacitor is connected to the LD pin, it charges at a rate that is determined by the current source during the DLD true time but is discharged nearly instantly when DLD is false. By monitoring the voltage at the LD pin (top of the capacitor), it is possible to get a logic high level only after the DLD has been true for a sufficiently long time. Any momentary DLD false resets the charging. By selecting a properly sized capacitor, it is possible to delay a lock detect indication until the PLL is stably locked and the lock detect does not chatter. The voltage on the capacitor can be sensed by an external comparator connected to the LD pin. However, there is an internal LD pin comparator that can be read at the REFMON pin control (Register 0x01B[4:0]) or the STATUS pin control (Register 0x017[7:2]) as an active high signal. It is also available as an active low signal (REFMON, Register 0x01B[4:0] and STATUS, Register 0x017[7:2]). The internal LD pin comparator trip point and hysteresis are listed in Table 16. AD9517-4 110µA Analog Lock Detect (ALD) The AD9517 provides an ALD function that can be selected for use at the LD pin. There are two versions of ALD, as follows: • N-channel open-drain lock detect. This signal requires a pull-up resistor to the positive supply, VS. The output is normally high with short, low-going pulses. Lock is indicated by the minimum duty cycle of the low-going pulses. P-channel open-drain lock detect. This signal requires a pull-down resistor to GND. The output is normally low with short, high-going pulses. Lock is indicated by the minimum duty cycle of the high-going pulses. The analog lock detect function requires an R-C filter to provide a logic level indicating lock/unlock. C LD PIN COMPARATOR REFMON OR STATUS Figure 51. Current Source Lock Detect External VCXO/VCO Clock Input (CLK/CLK) CLK is a differential input that can be used as an input to drive the AD9517 clock distribution section. This input can receive up to 2.4 GHz. The pins are internally self-biased, and the input signal should be ac-coupled via capacitors. CLOCK INPUT STAGE VS = 3.3V AD9517-4 R2 LD VS VOUT CLK C CLK 06428-067 ALD R1 VOUT LD 2.5kΩ 2.5kΩ 5kΩ Figure 50. Example of Analog Lock Detect Filter Using N-Channel Open-Drain Driver 5kΩ Current Source Digital Lock Detect (DLD) During the PLL locking sequence, it is normal for the DLD signal to toggle a number of times before remaining steady when the PLL is completely locked and stable. There may be applications where it is desirable to have DLD asserted only after the PLL is solidly locked. This is made possible by using the current source lock detect function. This function is set 06428-032 • DLD 06428-068 DIGITAL LOCK DETECT (DLD) Figure 52. CLK Equivalent Input Circuit The CLK/CLK input can be used either as a distribution-only input (with the PLL off), or as a feedback input for an external VCO/VCXO using the internal PLL when the internal VCO is not used. The CLK/CLK input can be used for frequencies up to 2.4 GHz. Rev. E | Page 37 of 80 AD9517-4 Data Sheet Holdover Automatic/Internal Holdover Mode The AD9517 PLL has a holdover function. Holdover is implemented by putting the charge pump into a state of high impedance. This is useful when the PLL reference clock is lost. Holdover mode allows the VCO to maintain a relatively constant frequency even though there is no reference clock. Without this function, the charge pump is placed into a constant pump-up or pump-down state, resulting in a massive VCO frequency shift. Because the charge pump is placed in a high impedance state, any leakage that occurs at the charge pump output or the VCO tuning node causes a drift of the VCO frequency. This can be mitigated by using a loop filter that contains a large capacitive component because this drift is limited by the current leakage induced slew rate (ILEAK/C) of the VCO control voltage. For most applications, the frequency accuracy is sufficient for 3 sec to 5 sec. When enabled, this function automatically puts the charge pump into a high impedance state when the loop loses lock. The assumption is that the only reason the loop loses lock is due to the PLL losing the reference clock; therefore, the holdover function puts the charge pump into a high impedance state to maintain the VCO frequency as close as possible to the original frequency before the reference clock disappears. See Figure 53 for a flowchart of the automatic/internal holdover function operation. PLL ENABLED DLD == LOW Both a manual holdover, using the SYNC pin, and an automatic holdover mode are provided. To use either function, the holdover function must be enabled (Register 0x01D[0] and Register 0x01D[2]). YES YES CHARGE PUMP IS MADE HIGH IMPEDANCE. PLL COUNTERS CONTINUE OPERATING NORMALLY. HIGH IMPEDANCE CHARGE PUMP YES NO CHARGE PUMP REMAINS HIGH IMPEDANCE UNTIL THE REFERENCE HAS RETURNED. REFERENCE EDGE AT PFD? YES YES TAKE CHARGE PUMP OUT OF HIGH IMPEDANCE. PLL CAN NOW RESETTLE. RELEASE CHARGE PUMP HIGH IMPEDANCE The B-counter (in the N divider) is reset synchronously with the charge pump leaving the high impedance state on the reference path PFD event. This helps align the edges out of the R and N dividers for faster settling of the PLL. Because the prescaler is not reset, this feature works best when the B and R numbers are close because this results in a smaller phase difference for the loop to settle out. When using this mode, set the channel dividers to ignore the SYNC pin (at least after an initial SYNC event). If the dividers are not set to ignore the SYNC pin, the distribution outputs turn off each time SYNC is taken low to put the part into holdover. ANALOG LOCK DETECT PIN INDICATES LOCK WAS PREVIOUSLY ACHIEVED. (0x1D[3] = 1: USE LD PIN VOLTAGE WITH HOLDOVER. 0x1D[3] = 0: IGNORE LD PIN VOLTAGE, TREAT LD PIN AS ALWAYS HIGH.) WAS LD PIN == HIGH WHEN DLD WENT LOW? Manual Holdover Mode A manual holdover mode can be enabled that allows the user to place the charge pump into a high impedance state when the SYNC pin is asserted low. This operation is edge sensitive, not level sensitive. The charge pump enters a high impedance state immediately. To take the charge pump out of a high impedance state, take the SYNC pin high. The charge pump then leaves high impedance state synchronously with the next PFD rising edge from the reference clock. This prevents extraneous charge pump events from occurring during the time between SYNC going high and the next PFD event. This also means that the charge pump stays in a high impedance state as long as there is no reference clock present. NO YES NO DLD == HIGH WAIT FOR DLD TO GO HIGH. THIS TAKES 5 TO 255 CYCLES (PROGRAMMING OF THE DLD DELAY COUNTER) WITH THE REFERENCE AND FEEDBACK CLOCKS INSIDE THE LOCK WINDOW AT THE PFD. THIS ENSURES THAT THE HOLDOVER FUNCTION WAITS FOR THE PLL TO SETTLE AND LOCK BEFORE THE HOLDOVER FUNCTION CAN BE RETRIGGERED. 06428-069 Note that the VCO cannot be calibrated with the holdover enabled because the holdover resets the N divider during calibration, which prevents proper calibration. Disable holdover before issuing a VCO calibration. LOOP OUT OF LOCK. DIGITAL LOCK DETECT SIGNAL GOES LOW WHEN THE LOOP LEAVES LOCK AS DETERMINED BY THE PHASE DIFFERENCE AT THE INPUT OF THE PFD. NO Figure 53. Flowchart of Automatic/Internal Holdover Mode The holdover function senses the logic level of the LD pin as a condition to enter holdover. The signal at LD can be from the DLD, ALD, or current source LD mode. It is possible to disable the LD comparator (Register 0x01D[3]), which causes the holdover function to always sense LD as high. Rev. E | Page 38 of 80 Data Sheet AD9517-4 If DLD is used, it is possible for the DLD signal to chatter some while the PLL is reacquiring lock. The holdover function may retrigger, thereby preventing the holdover mode from ever terminating. Use of the current source lock detect mode is recommended to avoid this situation (see the Current Source Digital Lock Detect section). For example, to use automatic holdover with the following: Once in holdover mode, the charge pump stays in a high impedance state as long as there is no reference clock present. • • • • As in the external holdover mode, the B counter (in the N divider) is reset synchronously with the charge pump leaving the high impedance state on the reference path PFD event. This helps align the edges out of the R and N dividers for faster settling of the PLL and to reduce frequency errors during settling. Because the prescaler is not reset, this feature works best when the B and R numbers are close because this results in a smaller phase difference for the loop to settle out. After leaving holdover, the loop then reacquires lock and the LD pin must charge (if Register 0x01D[3] = 1) before it can re-enter holdover (CP high impedance). The holdover function always responds to the state of the currently selected reference (Register 0x01C). If the loop loses lock during a reference switchover (see the Reference Switchover section), holdover is triggered briefly until the next reference clock edge at the PFD. The following registers affect the internal/automatic holdover function: • • • • • • Register 0x018[6:5], lock detect counter. These bits change the number of consecutive PFD cycles with edges inside the lock detect window that are required for the DLD indicator to indicate lock. This impacts the time required before the LD pin can begin to charge as well as the delay from the end of a holdover event until the holdover function can be reengaged. Register 0x018[3], disable digital lock detect. This bit must be set to 0b to enable the DLD circuit. Internal/automatic holdover does not operate correctly without the DLD function enabled. Register 0x01A[5:0], lock detect pin output select. Set these bits to 000100b for the current source lock detect mode if using the LD pin comparator. Load the LD pin with a capacitor of an appropriate value. Register 0x01D[3], enable LD pin comparator. 1 = enable, 0 = disable. When disabled, the holdover function always senses the LD pin as high. Register 0x01D[1], enable external holdover control. Register 0x01D[0] and Register 0x01D[2], holdover function enable. If holdover is disabled, both external and internal/automatic holdover are disabled. • • • Automatic reference switchover, prefer REF1 Digital lock detect: five PFD cycles, high range window Automatic holdover using the LD pin comparator Set the following registers (in addition to the normal PLL registers): • • • • • • • Register 0x018[6:5] = 00b; lock detect counter = five cycles. Register 0x018[4] = 0b; lock detect window = high range. Register 0x018[3] = 0b; DLD normal operation. Register 0x01A[5:0] = 000100b; current source lock detect mode. Register 0x01B[7:0] = 0xF7; set REFMON pin to status of REF1 (active low). Register 0x01C[2:1] = 11b; enable REF1 and REF2 input buffers. Register 0x01D[3] = 1b; enable LD pin comparator. Register 0x01D[2]=1b; enable the holdover function. Register 0x01D[1] = 0b; use internal/automatic holdover mode. Register 0x01D[0] = 1b; enable the holdover function. (VCO calibration must be complete before this bit is enabled.) Connect REFMON pin to REFSEL pin. Frequency Status Monitors The AD9517 contains three frequency status monitors that are used to indicate if the PLL reference (or references in the case of single-ended mode) and the VCO have fallen below a threshold frequency. A diagram showing their location in the PLL is shown in Figure 54. The VCO status frequency monitor is also capable of monitoring the CLK input if the CLK input is selected as the input to the N divider. The PLL reference frequency monitors have two threshold frequencies: normal and extended (see Table 16.). The reference frequency monitor thresholds are selected in Register 0x01A. The frequency monitor status can be found in Register 0x01F, Bits[3:1]. Rev. E | Page 39 of 80 AD9517-4 Data Sheet REF_SEL VS GND RSET REFMON CPRSET VCP DISTRIBUTION REFERENCE REFERENCE SWITCHOVER LD REF1 STATUS R DIVIDER STATUS REFIN (REF1) PLL REFERENCE REF2 LOCK DETECT PROGRAMMABLE R DELAY REFIN (REF2) BYPASS LOW DROPOUT REGULATOR (LDO) N DIVIDER P, P + 1 PRESCALER A/B COUNTERS LF PROGRAMMABLE N DELAY PHASE FREQUENCY DETECTOR HOLD CHARGE PUMP CP VCO STATUS VCO STATUS 0 DIVIDE BY 2, 3, 4, 5, OR 6 CLK 1 1 06428-070 CLK 0 Figure 54. Reference and VCO Status Monitors VCO Calibration The AD9517 on-chip VCO must be calibrated to ensure proper operation over process and temperature. VCO calibration centers the dc voltage at the internal VCO input (at the LF pin) for the selected configuration; this is normally required only during initial configuration and any time the PLL settings change. VCO calibration is controlled by a calibration controller driven by the R divider output. The calibration requires that the input reference clock be present at the REFIN pins, and that the PLL be set up properly to lock the PLL loop. During the first initialization after a power-up or a reset of the AD9517, a VCO calibration sequence is initiated by setting Register 0x018[0] = 1b. This can be done during initial setup, before executing an update registers (Register 0x232[0] = 1b). Subsequent to initial setup, a VCO calibration sequence is initiated by resetting Register 0x018[0] = 0b, executing an update registers operation, setting Register 0x018[0] = 1b, and executing another update registers operation. A readback bit, Bit 6 in Register 0x1F, indicates when a VCO calibration is finished by returning a logic true (that is, 1b). The sequence of operations for the VCO calibration is as follows: 1. 2. 3. 4. 5. 6. Program the PLL registers to the proper values for the PLL loop. Note that that automatic holdover mode must be disabled, and the VCO divider must not be set to “Static.” Ensure that the input reference signal is present. For the initial setting of the registers after a power-up or reset, initiate VCO calibration by setting Register 0x018[0] = 1b. Subsequently, whenever a calibration is desired, set Register 0x018[0] = 0b, update registers; and then set Register 0x018[0] = 1b, update registers. A sync operation is initiated internally, causing the outputs to go to a static state determined by normal sync function operation. The VCO calibrates to the desired setting for the requested VCO frequency. Internally, the SYNC signal is released, allowing outputs to continue clocking. 7. 8. The PLL loop is closed. The PLL locks. A sync is executed during the VCO calibration; therefore, the outputs of the AD9517 are held static during the calibration, which prevents unwanted frequencies from being produced. However, at the end of a VCO calibration, the outputs may resume clocking before the PLL loop is completely settled. The VCO calibration clock divider is set as shown in Table 54 (Register 0x018[2:1]). The calibration divider divides the PFD frequency (reference frequency divided by R) down to the calibration clock. The calibration occurs at the PFD frequency divided by the calibration divider setting. Lower VCO calibration clock frequencies result in longer times for a calibration to be completed. The VCO calibration clock frequency is given by fCAL_CLOCK = fREFIN/(R × cal_div) where: fREFIN is the frequency of the REFIN signal. R is the value of the R divider. cal_div is the division set for the VCO calibration divider (Register 0x018[2:1]). The VCO calibration takes 4400 calibration clock cycles. Therefore, the VCO calibration time in PLL reference clock cycles is given by Time to Calibrate VCO = 4400 × R × cal_div PLL Reference Clock Cycles Table 29. Example Time to Complete a VCO Calibration with Different fREFIN Frequencies fREFIN (MHz) 100 10 10 Rev. E | Page 40 of 80 R Divider 1 10 100 PFD 100 MHz 1 MHz 100 kHz Time to Calibrate VCO 88 μs 8.8 ms 88 ms Data Sheet AD9517-4 VCO calibration must be manually initiated. This allows for flexibility in deciding what order to program registers and when to initiate a calibration, instead of having it happen every time certain PLL registers have their values change. For example, this allows for the VCO frequency to be changed by small amounts without having an automatic calibration occur each time; this should be done with caution and only when the user knows that the VCO control voltage is not going to exceed the nominal best performance limits. For example, a few 100 kHz steps are fine, but a few MHz might not be. In addition, because the calibration procedure results in rapid changes in the VCO frequency, the distribution section is automatically placed in SYNC until the calibration is finished. Therefore, this temporary loss of outputs must be expected. A VCO calibration should be initiated under the following conditions: • • After changing any of the PLL R, P, B, and A divider settings, or after a change in the PLL reference clock frequency. This, in effect, means any time a PLL register or reference clock is changed such that a different VCO frequency results. Whenever system calibration is desired. The VCO is designed to operate properly over extremes of temperatures even when it is first calibrated at the opposite extreme. However, a VCO calibration can be initiated at any time, if desired. CLOCK DISTRIBUTION A clock channel consists of a pair (or double pair, in the case of CMOS) of outputs that share a common divider. A clock output consists of the drivers that connect to the output pins. The clock outputs have either LVPECL or LVDS/CMOS signal levels at the pins. The AD9517 has four clock channels: two channels are LVPECL (four outputs); two channels are LVDS/CMOS (up to four LVDS outputs or up to eight CMOS outputs). Each channel has its own programmable divider that divides the clock frequency that is applied to its input. The LVPECL channel dividers can divide by any integer from 2 to 32, or the divider can be bypassed to achieve a divide by one. Each LVDS/CMOS channel divider contains two of these divider blocks in a cascaded configuration. The total division of the channel is the product of the divide value of the cascaded dividers. This allows divide values of (1 to 32) × (1 to 32), or up to 1024 (note that this is not all values from 1 to 1024 but only the set of numbers that are the product of the two dividers). If the user wishes to use the channel dividers, the VCO divider must be used after the on-chip VCO. This is because the internal VCO frequency is above the maximum channel divider input frequency (1600 MHz). The VCO divider can be set to divide by 2, 3, 4, 5, or 6. External clock signals connected to the CLK input also require the VCO divider if the frequency of the signal is greater than 1600 MHz. The channel dividers allow for a selection of various duty cycles, depending on the currently set division. That is, for any specific division, D, the output of the divider can be set to high for N + 1 input clock cycles and low for M + 1 input clock cycles (where D = N + M + 2). For example, a divide-by-5 can be high for one divider input cycle and low for four cycles, or a divideby-5 can be high for three divider input cycles and low for two cycles. Other combinations are also possible. The channel dividers include a duty-cycle correction function that can be disabled. In contrast to the selectable duty cycle just described, this function can correct a non-50% duty cycle caused by an odd division. However, this requires that the division be set by M = N + 1. In addition, the channel dividers allow a coarse phase offset or delay to be set. Depending on the division selected, the output can be delayed by up to 31 input clock cycles. The divider outputs can also be set to start high or start low. Internal VCO or External CLK as Clock Source The clock distribution of the AD9517 has two clock input sources: an internal VCO or an external clock connected to the CLK/CLK pins. Either the internal VCO or CLK must be chosen as the source of the clock signal to distribute. When the internal VCO is selected as the source, the VCO divider must be used. When CLK is selected as the source, it is not necessary to use the VCO divider if the CLK frequency is less than the maximum channel divider input frequency (1600 MHz); otherwise, the VCO divider must be used to reduce the frequency to one acceptable by the channel dividers. Table 30 shows how the VCO, CLK, and VCO divider are selected. Register 0x1E1[1:0] selects the channel divider source and determines whether the VCO divider is used. It is not possible to select the VCO without using the VCO divider. Table 30. Selecting VCO or CLK as Source for Channel Divider, and Whether VCO Divider Is Used Register 0x1E1 Bit 1 Bit 0 0 0 0 1 1 0 1 1 Channel Divider Source CLK CLK VCO Not allowed VCO Divider Used Not used Used Not allowed CLK or VCO Direct to LVPECL Outputs It is possible to connect either the internal VCO or the CLK (whichever is selected as the input to the VCO divider) directly to the LVPECL outputs, OUT0 to OUT3. This configuration can pass frequencies up to the maximum frequency of the VCO directly to the LVPECL outputs. The LVPECL outputs may not be able to provide a full voltage swing at the highest frequencies. Rev. E | Page 41 of 80 AD9517-4 Data Sheet To connect the LVPECL outputs directly to the internal VCO or CLK, the VCO divider must be selected as the source to the distribution section, even if no channel uses it. Either the internal VCO or the CLK can be selected as the source for the direct-to-output routing. Table 31. Settings for Routing VCO Divider Input Directly to LVPECL Outputs Register Setting 0x1E1[1:0] = 00b 0x1E1[1:0] = 10b 0x192[1] = 1b 0x198[1] = 1b Selection CLK is the source; VCO divider selected VCO is the source; VCO divider selected Direct to OUT0 and OUT1 outputs Direct to OUT2 and OUT3 outputs VCO Divider Clock Frequency Division The total frequency division is a combination of the VCO divider (when used) and the channel divider. When the VCO divider is used, the total division from the VCO or CLK to the output is the product of the VCO divider (2, 3, 4, 5, and 6) and the division of the channel divider. Table 32 and Table 33 indicate how the frequency division for a channel is set. For the LVPECL outputs, there is only one divider per channel. For the LVDS/ CMOS outputs, there are two dividers (X.1, X.2) cascaded per channel. Table 32. Frequency Division for Divider 0 and Divider 1 CLK or VCO Selected CLK/VCO CLK/VCO CLK/VCO VCO Divider 2 to 6 2 to 6 2 to 6 Channel Divider 1 (bypassed) 1 (bypassed) 2 to 32 Direct to Output Yes No No CLK CLK Not used Not used 1 (bypassed) 2 to 32 No No Frequency Division 1 (2 to 6) × (1) (2 to 6) × (2 to 32) 1 2 to 32 Table 33. Frequency Division for Divider 2 and Divider 3 CLK or VCO Selected CLK/VCO VCO Divider 2 to 6 CLK/VCO 2 to 6 CLK/VCO 2 to 6 Channel Divider X.1 X.2 1 1 (bypassed) (bypassed) 2 to 32 1 (bypassed) 2 to 32 2 to 32 CLK CLK CLK Not used Not used Not used 1 2 to 32 2 to 32 1 1 2 to 32 The channel dividers feeding the LVPECL output drivers contain one 2-to-32 frequency divider. This divider provides for division by 2 to 32. Division by 1 is accomplished by bypassing the divider. The dividers also provide for a programmable duty cycle, with optional duty-cycle correction when the divide ratio is odd. A phase offset or delay in increments of the input clock cycle is selectable. The channel dividers operate with a signal at their inputs up to 1600 MHz. The features and settings of the dividers are selected by programming the appropriate setup and control registers (see Table 52 through Table 62). Frequency Division (2 to 6) × (1) × (1) (2 to 6) × (2 to 32) × (1) (2 to 6) × (2 to 32) × (2to 32) 1 (2 to 32) × (1) 2 to 32 × (2 to 32) The VCO divider provides frequency division between the internal VCO or the external CLK input and the clock distribution channel dividers. The VCO divider can be set to divide by 2, 3, 4, 5, or 6 (see Table 60, Register 0x1E0[2:0]). Channel Dividers—LVPECL Outputs Each pair of LVPECL outputs is driven by a channel divider. There are two channel dividers (0, 1) driving four LVPECL outputs (OUT0 to OUT3). Table 34 gives the register locations used for setting the division and other functions of these dividers. The division is set by the values of M and N. The divider can be bypassed (equivalent to divide-by-1, divider circuit is powered down) by setting the bypass bit. The duty-cycle correction can be enabled or disabled according to the setting of the DCCOFF bits. Table 34. Setting DX for Divider 0 and Divider 11 Divider 0 1 1 Low Cycles M 0x190[7:4] 0x196[7:4] High Cycles N 0x190[3:0] 0x196[3:0] Bypass 0x191[7] 0x197[7] DCCOFF 0x192[0] 0x198[0] Note that the value stored in the register = # of cycles minus 1. Channel Frequency Division (0, 1) For each channel (where the channel number is x: 0, 1), the frequency division, DX, is set by the values of M and N (four bits each, representing Decimal 0 to Decimal 15), where Number of Low Cycles = M + 1 Number of High Cycles = N + 1 The cycles are cycles of the clock signal currently routed to the input of the channel dividers (VCO divider out or CLK). When a divider is bypassed, DX = 1. Otherwise, DX = (N + 1) + (M + 1) = N + M + 2. This allows each channel divider to divide by any integer from 2 to 32. Rev. E | Page 42 of 80 Data Sheet AD9517-4 Duty Cycle and Duty-Cycle Correction (0, 1) The duty cycle of the clock signal at the output of a channel is a result of some or all of the following conditions: • • • • What are the M and N values for the channel? Is the DCC enabled? Is the VCO divider used? What is the CLK input duty cycle? (The internal VCO has a 50% duty cycle.) Table 36. Duty Cycle with VCO Divider; Input Duty Cycle Is X% VCO Divider Even Odd = 3 Odd = 5 DX N+M+2 1 (divider bypassed) 1 (divider bypassed) 1 (divider bypassed) Even The DCC function is enabled by default for each channel divider. However, the DCC function can be disabled individually for each channel divider by setting the DCCOFF bit for that channel. Even Certain M and N values for a channel divider result in a non-50% duty cycle. A non-50% duty cycle can also result with an even division, if M ≠ N. The duty-cycle correction function automatically corrects non-50% duty cycles at the channel divider output to 50% duty cycle. Duty-cycle correction requires the following channel divider conditions: Odd = 3 Even Odd = 3 Odd Odd = 5 Even Odd = 5 Odd • • An even division must be set as M = N. An odd division must be set as M = N + 1. When not bypassed or corrected by the DCC function, the duty cycle of each channel divider output is the numerical value of (N + 1)/(N + M + 2), expressed as a percentage (%). N+M+2 1 Output Duty Cycle DCCOFF = 1 DCCOFF = 0 50% 50% Any Even 50% Odd 33.3% 50% X% Odd 40% 50% (N + 1)/ (N + M + 2) (N + 1)/ (N + M + 2) 50%; requires M = N Table 35. Duty Cycle with VCO Divider; Input Duty Cycle Is 50% Even, Odd DX N+M+2 1 (divider bypassed) 1 (divider bypassed) 1 (divider bypassed) Even Even, Odd Odd Odd = 3 Odd = 5 50%; requires M = N + 1 33.3% (1 + X%)/3 40% (2 + X%)/5 (N + 1)/ (N + M + 2) (N + 1)/ (N + M + 2) (N + 1)/ (N + M + 2) (N + 1)/ (N + M + 2) (N + 1)/ (N + M + 2) (N + 1)/ (N + M + 2) 50%, requires M = N 50%, requires M = N + 1 50%, requires M = N (3N + 4 + X%)/(6N + 9), requires M = N + 1 50%, requires M = N (5N + 7 + X%)/(10N + 15), requires M = N + 1 Table 37. Channel Divider Output Duty Cycle When the VCO Divider Is Not Used Input Clock Duty Cycle Any The duty cycle at the output of the channel divider for various configurations is shown in Table 35 to Table 37. VCO Divider Even Odd Output Duty Cycle DCCOFF = 1 DCCOFF = 0 50% 50% DX Output Duty Cycle DCCOFF = 1 1 (divider bypassed) (N + 1)/ (M + N + 2) (N + 1)/ (M + N + 2) (N + 1)/ (M + N + 2) DCCOFF = 0 Same as input duty cycle 50%, requires M = N 50%, requires M=N+1 (N + 1 + X%)/(2 × N + 3), requires M = N + 1 The internal VCO has a duty cycle of 50%. Therefore, when the VCO is connected directly to the output, the duty cycle is 50%. If the CLK input is routed directly to the output, the duty cycle of the output is the same as the CLK input. Rev. E | Page 43 of 80 AD9517-4 Data Sheet Phase Offset or Coarse Time Delay (0, 1) Channel Dividers—LVDS/CMOS Outputs Each channel divider allows for a phase offset, or a coarse time delay, to be programmed by setting register bits (see Table 38). These settings determine the number of cycles (successive rising edges) of the channel divider input frequency by which to offset, or delay, the rising edge of the output of the divider. This delay is with respect to a nondelayed output (that is, with a phase offset of zero). The amount of the delay is set by five bits loaded into the phase offset (PO) register plus the start high (SH) bit for each channel divider. When the start high bit is set, the delay is also affected by the number of low cycles (M) that are programmed for the divider. Channel Divider 2 and Channel Divider 3 each drive a pair of LVDS outputs, giving a total of four LVDS outputs (OUT4 to OUT7). Alternatively, each of these LVDS differential outputs can be configured individually as a pair (A and B) of CMOS single-ended outputs, providing for up to eight CMOS outputs. By default, the B output of each pair is off but can be turned on as desired. The sync function must be used to make phase offsets effective (see the Synchronizing the Outputs—Sync Function section). Table 38. Setting Phase Offset and Division for Divider 0 and Divider 1 Divider 0 1 Start High (SH) 0x191[4] 0x197[4] Phase Offset (PO) 0x191[3:0] 0x197[3:0] Low Cycles M 0x190[7:4] 0x196[7:4] High Cycles N 0x190[3:0] 0x196[3:0] Let Δt = delay (in seconds). Δc = delay (in cycles of clock signal at input to DX). TX = period of the clock signal at the input of the divider, DX (in seconds). Φ = 16 × SH[4] + 8 × PO[3] + 4 × PO[2] + 2 × PO[1] + 1 × PO[0] The channel divide-by is set as N = high cycles and M = low cycles. Channel Divider 2 and Channel Divider 3 each consist of two cascaded, 2 to 32, frequency dividers. The channel frequency division is DX.1 × DX.2 or up to 1024. Divide-by-1 is achieved by bypassing one or both of these dividers. Both of the dividers also have DCC enabled by default, but this function can be disabled, if desired, by setting the DCCOFF bit of the channel. A coarse phase offset or delay is also programmable (see the Phase Offset or Coarse Time Delay (Divider 2 and Divider 3) section). The channel dividers operate up to 1600 MHz. The features and settings of the dividers are selected by programming the appropriate setup and control registers (see Table 52 and Table 53 through Table 62). Table 39. Setting Division (DX) for Divider 2, Divider 31 Divider 2 2.1 2.2 3 3.1 3.2 1 M 0x199[7:4] 0x19B[7:4] 0x19E[7:4] 0x1A0[7:4] N 0x199[3:0] 0x19B[3:0] 0x19E[3:0] 0x1A0[3:0] Bypass 0x19C[4] 0x19C[5] 0x1A1[4] 0x1A1[5] DCCOFF 0x19D[0] 0x19D[0] 0x1A2[0] 0x1A2[0] Note that the value stored in the register = # of cycles minus 1. Case 1 Channel Frequency Division (Divider 2 and Divider 3) For Φ ≤ 15: Δt = Φ × TX Δc = Δt/TX = Φ The division for each channel divider is set by the bits in the registers for the individual dividers (X.Y = 2.1, 2.2, 3.1, and 3.2) Number of Low Cycles = MX.Y + 1 Case 2 Number of High Cycles = NX.Y + 1 For Φ ≥ 16: Δt = (Φ − 16 + M + 1) × TX Δc = Δt/TX When both X.1 and X.2 are bypassed, DX = 1 × 1 = 1. When only X.2 is bypassed, DX = (NX.1 + MX.1 + 2) × 1. By giving each divider a different phase offset, output-to-output delays can be set in increments of the channel divider input clock cycle. Figure 55 shows the results of setting such a coarse offset between outputs. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CHANNEL DIVIDER INPUT Tx DIVIDER 2 SH = 0 PO = 2 1 × Tx 2 × Tx 06428-071 SH = 0 PO = 1 By cascading the dividers, channel division up to 1024 can be obtained. However, not all integer value divisions from 1 to 1024 are obtainable; only the values that are the product of the separate divisions of the two dividers (DX.1 × DX.2) can be realized. If only one divider is needed when using Divider 2 and Divider 3, use the first one (X.1) and bypass the second one (X.2). Do not bypass X.1 and use X.2. CHANNEL DIVIDER OUTPUTS DIV = 4, DUTY = 50% SH = 0 DIVIDER 0 PO = 0 DIVIDER 1 When both X.1 and X.2 are not bypassed, DX = (NX.1 + MX.1 + 2) × (NX.2 + MX.2 + 2). Figure 55. Effect of Coarse Phase Offset (or Delay) Rev. E | Page 44 of 80 Data Sheet AD9517-4 Duty Cycle and Duty-Cycle Correction (Divider 2 and Divider 3) The same duty cycle and DCC considerations apply to Divider 2 and Divider 3 as to Divider 0 and Divider 1 (see the Duty Cycle and Duty-Cycle Correction (0, 1) section); however, with these channel dividers, the number of possible configurations is even more complex. Duty-cycle correction on Divider 2 and Divider 3 requires the following channel divider conditions: • • • • An even DX.Y must be set as MX.Y = NX.Y (low cycles = high cycles). An odd DX.Y must be set as MX.Y = NX.Y + 1 (the number of low cycles must be one greater than the number of high cycles). If only one divider is bypassed, it must be the second divider, X.2. If only one divider has an even divide-by, it must be the second divider, X.2. The possibilities for the duty cycle of the output clock from Divider 2 and Divider 3 are shown in Table 40 through Table 44. Table 40. Divider 2 and Divider 3 Duty Cycle; VCO Divider Used; Duty Cycle Correction Off (DCCOFF = 1) VCO Divider Even Odd = 3 Odd = 5 Even DX.1 NX.1 + MX.1 + 2 1 1 1 Even, odd DX.2 NX.2 + MX.2 + 2 1 1 1 1 Odd Even, odd 1 Even Even, odd Even, odd Odd Even, odd Even, odd Output Duty Cycle 50% 33.3% 40% (NX.1 + 1)/ (NX.1 + MX.1 + 2) (NX.1 + 1)/ (NX.1 + MX.1 + 2) (NX.2 + 1)/ (NX.2 + MX.2 + 2) (NX.2 + 1)/ (NX.2 + MX.2 + 2) Table 42. Divider 2 and Divider 3 Duty Cycle; VCO Divider Used; Duty Cycle Correction Is On (DCCOFF = 0); VCO Divider Input Duty Cycle = 50% VCO Divider Even Odd Even Odd Even Odd Even Odd Even Odd Even Odd Input Clock Duty Cycle 50% X% 50% DX.1 NX.1 + MX.1 + 2 1 1 Even, odd DX.2 NX.2 + MX.2 + 2 1 1 1 X% Even, odd 1 50% Even, odd Even, odd X% Even, odd Even, odd Output Duty Cycle 50% X% (NX.1 + 1)/ (NX.1 + MX.1 + 2) (NX.1 + 1)/ (NX.1 + MX.1 + 2) (NX.2 + 1)/ (NX.2 + MX.2 + 2) (NX.2 + 1)/ (NX.2 + MX.2 + 2) DX.2 NX.2 + MX.2 + 2 1 1 1 1 1 1 Even (NX.2 = MX.2) Even (NX.2 = MX.2) Even (NX.2 = MX.2) Even (NX.2 = MX.2) Odd (MX.2 = NX.2 + 1) Odd (MX.2 = NX.2 + 1) Output Duty Cycle 50% 50% 50% 50% 50% 50% 50% 50% 50% 50% 50% 50% Table 43. Divider 2 and Divider 3 Duty Cycle; VCO Divider Used; Duty Cycle Correction On (DCCOFF = 0); VCO Divider Input Duty Cycle = X% VCO Divider Even Odd = 3 Odd = 5 Even Odd Even Odd = 3 Odd = 5 Even Odd Table 41. Divider 2 and Divider 3 Duty Cycle; VCO Divider Not Used; Duty Cycle Correction Off (DCCOFF = 1) DX.1 NX.1 + MX.1 + 2 1 1 Even (NX.1 = MX.1) Even (NX.1 = MX.1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Even (NX.1 = MX.1) Even (NX.1 = MX.1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Even Odd Even Odd = 3 Odd = 5 Rev. E | Page 45 of 80 DX.1 DX.2 NX.1 + MX.1 + 2 1 1 1 Even (NX.1 = MX.1) Even (NX.1 = MX.1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Even (NX.1 = MX.1) Even (NX.1 = MX.1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) NX.2 + MX.2 + 2 1 1 1 Output Duty Cycle 50% (1 + X%)/3 (2 + X%)/5 1 50% 1 50% 1 50% Odd (MX.1 = NX.1 + 1) Odd (MX.2 = NX.2 + 1) 1 1 Even (NX.2 = MX.2) Even (NX.2 = MX.2) Even (NX.2 = MX.2) Even (NX.2 = MX.2) Odd (MX.2 = NX.2 + 1) Odd (MX.2 = NX.2 + 1) (3NX.1 + 4 + X%)/ (6NX.1 + 9) (5NX.1 + 7 + X%)/ (10NX.1 + 15) 50% 50% 50% 50% 50% (6NX.1NX.2 + 9NX.1 + 9NX.2 + 13 + X%)/ (3(2NX.1 + 3) (2NX.2 + 3)) (10NX.1NX.2 + 15NX.1 + 15NX.2 + 22 + X%)/ (5(2 NX.1 + 3) (2 NX.2 + 3)) AD9517-4 Data Sheet Table 44. Divider 2 and Divider 3 Duty Cycle; VCO Divider Not Used; Duty Cycle Correction On (DCCOFF = 0) X% X% 50% X% 50% X% 50% X% 50% X% DX.1 DX.2 NX.1 + MX.1 + 2 1 Even (NX.1 = MX.1) 1 Even (NX.1 = MX.1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Even (NX.1 = MX.1) Even (NX.1 = MX.1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) Odd (MX.1 = NX.1 + 1) NX.2 + MX.2 + 2 1 1 Output Duty Cycle 50% 50% 1 1 X% (High) 50% 1 50% 1 (NX.1 + 1 + X%)/ (2NX.1 + 3) 50% Even (NX.2 = MX.2) Even (NX.2 = MX.2) Even (NX.2 = MX.2) Even (NX.2 = MX.2) Odd (MX.2 = NX.2 + 1) Odd (MX.2 = NX.2 + 1) Case 1 When Φx.1 ≤ 15 and Φx.2 ≤ 15: Δt = Φx.1 × TX.1 + ΦX.2 × Tx.2 Case 2 When Φx.1 ≤ 15 and Φx.2 ≥ 16: Δt = ΦX.1 × TX.1 + (ΦX.2 − 16 + MX.2 + 1) × TX.2 Case 3 When ΦX.1 ≥ 16 and ΦX.2 ≤ 15: 50% Δt = (ΦX.1 − 16 + MX.1 + 1) × TX.1 + ΦX.2 × TX.2 50% Case 4 When ΦX.1 ≥ 16 and ΦX.2 ≥ 16: 50% Δt = 50% (ΦX.1 − 16 + MX.1 + 1) × TX.1 + (ΦX.2 − 16 + MX.2 + 1) × TX.2 (2NX.1NX.2 + 3NX.1 + 3NX.2 + 4 + X%)/ ((2NX.1 + 3)(2NX.2 + 3)) Phase Offset or Coarse Time Delay (Divider 2 and Divider 3) Divider 2 and Divider 3 can be set to have a phase offset or delay. The phase offset is set by a combination of the bits in the phase offset and start high registers (see Table 45). Fine Delay Adjust (Divider 2 and Divider 3) Each AD9517 LVDS/CMOS output (OUT4 to OUT7) includes an analog delay element that can be programmed to give variable time delays (Δt) in the clock signal at that output. DIVIDER X.1 Table 45. Setting Phase Offset and Division for Divider 2 and Divider 3 Divider 2 2.1 2.2 3 3.1 3.2 Start High (SH) 0x19C[0] 0x19C[1] 0x1A1[0] 0x1A1[1] Phase Offset (PO) 0x19A[3:0] 0x19A[7:4] 0x19F[3:0] 0x19F[7:4] Low Cycles M 0x199[7:4] 0x19B[7:4] 0x19E[7:4] 0x1A0[7:4] High Cycles N 0x199[3:0] 0x19B[3:0] 0x19E[3:0] 0x1A0[3:0] BYPASS VCO CLK DIVIDER CMOS ΔT LVDS FINE DELAY ADJUST CMOS OUTM OUTM OUTPUT DRIVERS DIVIDER X.2 BYPASS CMOS ΔT LVDS FINE DELAY ADJUST CMOS OUTN OUTN 06428-072 Input Clock Duty Cycle 50% 50% Let Δt = delay (in seconds). Φx.y = 16 × SH[0] + 8 × PO[3] + 4 × PO[2] + 2 × PO[1] + 1 × PO[0]. TX.1 = period of the clock signal at the input to DX.1 (in seconds). TX.2 = period of the clock signal at the input to DX.2 (in seconds). Figure 56. Fine Delay (OUT4 to OUT7) The amount of delay applied to the clock signal is determined by programming four registers per output (see Table 46). Table 46. Setting Analog Fine Delays OUTPUT (LVDS/CMOS) OUT4 OUT5 OUT6 OUT7 Rev. E | Page 46 of 80 Ramp Capacitors 0x0A1[5:3] 0x0A4[5:3] 0x0A7[5:3] 0x0AA[5:3] Ramp Current 0x0A1[2:0] 0x0A4[2:0] 0x0A7[2:0] 0x0AA[2:0] Delay Fraction 0x0A2[5:0] 0x0A5[5:0] 0x0A8[5:0] 0x0AB[5:0] Delay Bypass 0x0A0[0] 0x0A3[0] 0x0A6[0] 0x0A9[0] Data Sheet AD9517-4 Synchronization of the outputs is executed in several ways, as follows: Calculating the Fine Delay The following values and equations are used to calculate the delay of the delay block. • IRAMP (µA) = 200 × (Ramp Current + 1) • Number of Capacitors = Number of Bits = 0 in Ramp Capacitors + 1 Example: 101 = 1 + 1 = 2; 110 = 1 + 1 = 2; 100 = 2 + 1 = 3; 001 = 2 + 1 = 3; 111 = 0 + 1 = 1. • Delay Range (ns) = 200 × ((No. of Caps + 3)/(IRAMP)) × 1.3286 No.of Caps − 1 ×6 Offset (ns ) = 0.34 + (1600 − I RAMP )× 10 + I RAMP Delay Full Scale (ns) = Delay Range + Offset • −4 Fine Delay (ns) = Delay Range × Delay Fraction × (1/63) + Offset Note that only delay fraction values up to 47 decimal (101111b; 0x2F) are supported. In no case can the fine delay exceed one-half of the output clock period. If a delay longer than half of the clock period is attempted, the output stops clocking. The delay function adds some jitter that is greater than that specified for the nondelayed output. This means that the delay function should be used primarily for clocking digital chips, such as FPGA, ASIC, DUC, and DDC. An output with this delay enabled may not be suitable for clocking data converters. The jitter is higher for long full scales because the delay block uses a ramp and trip points to create the variable delay. A slower ramp time produces more time jitter. Synchronizing the Outputs—Sync Function The AD9517 clock outputs can be synchronized to each other. Outputs can be individually excluded from synchronization. Synchronization consists of setting the nonexcluded outputs to a preset set of static conditions and subsequently releasing these outputs to continue clocking at the same instant with the preset conditions applied. This allows for the alignment of the edges of two or more outputs or for the spacing of edges according to the coarse phase offset settings for two or more outputs. • • By forcing the SYNC pin low and then releasing it (manual sync). By setting and then resetting any one of the following three bits: the soft sync bit (Register 0x230[0]), the soft reset bit (Register 0x000[2] [mirrored]), and the power-down distribution reference bit (Register 0x230[1]). By executing synchronization of the outputs as part of the chip power-up sequence. By forcing the RESET pin low and then releasing it (chip reset). By forcing the PD pin low and then releasing it (chip powerdown). Following completion of a VCO calibration. An internal SYNC signal is automatically asserted at the beginning of a VCO calibration and then released upon its completion. The most common way to execute the sync function is to use the SYNC pin to do a manual synchronization of the outputs. This requires a low-going signal on the SYNC pin, which is held low and then released when synchronization is desired. The timing of the sync operation is shown in Figure 57 (using VCO divider) and Figure 58 (VCO divider not used). There is an uncertainty of up to one cycle of the clock at the input to the channel divider due to the asynchronous nature of the SYNC signal with respect to the clock edges inside the AD9517. The delay from the SYNC rising edge to the beginning of synchronized output clocking is between 14 and 15 cycles of clock at the channel divider input, plus either one cycle of the VCO divider input (see Figure 57), or one cycle of the channel divider input (see Figure 58), depending on whether the VCO divider is used. Cycles are counted from the rising edge of the signal. Another common way to execute the sync function is by setting and resetting the soft sync bit at Register 0x230[0] (see Table 53 through Table 62 for details). Both the setting and resetting of the soft sync bit require an update all registers operation (Register 0x232[0] = 1) to take effect. Rev. E | Page 47 of 80 AD9517-4 Data Sheet CHANNEL DIVIDER OUTPUT CLOCKING CHANNEL DIVIDER OUTPUT CLOCKING CHANNEL DIVIDER OUTPUT STATIC INPUT TO VCO DIVIDER 1 1 INPUT TO CHANNEL DIVIDER 2 3 4 5 6 7 8 9 10 11 12 13 14 SYNC PIN OUTPUT OF CHANNEL DIVIDER 06428-073 14 TO 15 CYCLES AT CHANNEL DIVIDER INPUT + 1 CYCLE AT VCO DIVIDER INPUT Figure 57. SYNC Timing When VCO Divider Is Used—CLK or VCO Is Input CHANNEL DIVIDER OUTPUT CLOCKING CHANNEL DIVIDER OUTPUT CLOCKING CHANNEL DIVIDER OUTPUT STATIC INPUT TO CLK IINPUT TO CHANNEL DIVIDER 1 1 2 3 4 5 6 7 8 9 10 11 12 13 14 SYNC PIN OUTPUT OF CHANNEL DIVIDER 06428-074 14 TO 15 CYCLES AT CHANNEL DIVIDER INPUT + 1 CYCLE AT CLK INPUT Figure 58. SYNC Timing When VCO Divider Is Not Used—CLK Input Only A sync operation brings all outputs that have not been excluded (by the nosync bit) to a preset condition before allowing the outputs to begin clocking in synchronicity. The preset condition takes into account the settings in each of the channel’s start high bit and its phase offset. These settings govern both the static state of each output when the sync operation is happening and the state and relative phase of the outputs when they begin clocking again upon completion of the sync operation. Between outputs and after synchronization, this allows for the setting of phase offsets. The AD9517 outputs are in pairs, sharing a channel divider per pair (two pairs of pairs, four outputs, in the case of CMOS). The synchronization conditions apply to both outputs of a pair. Each channel (a divider and its outputs) can be excluded from any sync operation by setting the nosync bit of the channel. Channels that are set to ignore SYNC (excluded channels) do not set their outputs static during a sync operation, and their outputs are not synchronized with those of the nonexcluded channels. Clock Outputs The AD9517 offers three different output level choices: LVPECL, LVDS, and CMOS. OUT0 to OUT3 are LVPECL differential outputs; and OUT4 to OUT7 are LVDS/CMOS outputs. These outputs can be configured as either LVDS differential or as pairs of single-ended CMOS outputs. Rev. E | Page 48 of 80 Data Sheet AD9517-4 LVPECL Outputs—OUT0 to OUT3 3.5mA The LVPECL differential voltage (VOD) is selectable from ~400 mV to ~960 mV (see Register 0x0F0[3:2] to Register 0x0F5[3:2]). The LVPECL outputs have dedicated pins for power supply (VS_LVPECL), allowing a separate power supply to be used. VS_LVPECL can be from 2.5 V to 3.3 V. OUT 06428-034 The LVPECL output polarity can be set as noninverting or inverting, which allows for the adjustment of the relative polarity of outputs within an application without requiring a board layout change. Each LVPECL output can be powered down or powered up as needed. Because of the architecture of the LVPECL output stages, there is the possibility of electrical overstress and breakdown under certain power-down conditions. For this reason, the LVPECL outputs have several power-down modes. This includes a safe power-down mode that continues to protect the output devices while powered down, although it consumes somewhat more power than a total power-down. If the LVPECL output pins are terminated, it is best to select the safe power-down mode. If the pins are left floating (i.e., not connected), total power-down mode is fine. OUT 3.5mA Figure 60. LVDS Output Simplified Equivalent Circuit with 3.5 mA Typical Current Source Each LVDS/CMOS output can be powered-down as needed to save power. The CMOS output power-down is controlled by the same bit that controls the LVDS power-down for that output. This power-down control affects both CMOS Output A and CMOS Output B. However, when CMOS Output A is powered up, CMOS Output B can be powered on or off separately. VS 3.3V 06428-035 OUT OUT Figure 61. CMOS Equivalent Output Circuit OUT RESET MODES The AD9517 has several ways to force the chip into a reset condition that restores all registers to their default values and makes these settings active. Power-On Reset—Start-Up Conditions When VS Is Applied 06428-033 GND Figure 59. LVPECL Output Simplified Equivalent Circuit LVDS/CMOS Outputs—OUT4 to OUT7 OUT4 to OUT7 can be configured as either an LVDS differential output or as a pair of CMOS single-ended outputs. The LVDS outputs allow for selectable output current from ~1.75 mA to ~7 mA. The LVDS output polarity can be set as noninverting or inverting, which allows for the adjustment of the relative polarity of outputs within an application without requiring a board layout change. Each LVDS output can be powered down if not needed to save power. OUT4 to OUT7 can also be CMOS outputs. Each LVDS output can be configured to be two CMOS outputs. This provides for up to eight CMOS outputs: OUT4A, OUT4B, OUT5A, OUT5B, OUT6A, OUT6B, OUT7A, and OUT7B. When an output is configured as CMOS, CMOS Output A is automatically turned on. CMOS Output B can be turned on or off independently. The relative polarity of the CMOS outputs can also be selected for any combination of inverting and noninverting (see Table 57, Register 0x140[7:5], Register 0x141[7:5], Register 0x142[7:5], and Register 0x143[7:5]). A power-on reset (POR) is issued when the VS power supply is turned on. This initializes the chip to the power-on conditions that are determined by the default register settings. These are indicated in the Default Value (Hex) column of Table 52. At power-on, the AD9517 also executes a sync operation, which brings the outputs into phase alignment according to the default settings. Asynchronous Reset via the RESET Pin An asynchronous hard reset is executed by momentarily pulling RESET low. A reset restores the chip registers to the default settings. Soft Reset via Register 0x00[2] A soft reset is executed by writing Register 0x000[2] and Register 0x000[5] = 1b. This bit is not self-clearing; it must be cleared by writing Register 0x000[2] and Register 0x000[5] = 0b to reset it and complete the soft reset operation. A soft reset restores the default values to the internal registers. The soft reset bit does not require an update registers command (Register 0x232) to be issued. Rev. E | Page 49 of 80 AD9517-4 Data Sheet POWER-DOWN MODES In asynchronous power-down mode, the device powers down as soon as the registers are updated. Chip Power-Down via PD The AD9517 can be put into a power-down condition by pulling the PD pin low. Power-down turns off most of the functions and currents inside the AD9517. The chip remains in this power-down state until PD is brought back to logic high. When the AD9517 wakes up, it returns to the settings programmed into its registers prior to the power-down, unless the registers are changed by new programming while the PD pin is held low. The PD power-down shuts down the currents on the chip, except the bias current that is necessary to maintain the LVPECL outputs in a safe shutdown mode. This is needed to protect the LVPECL output circuitry from damage that could be caused by certain termination and load configurations when tristated. Because this is not a complete power-down, it can be called sleep mode. When the AD9517 is in a PD power-down, the chip is in the following state: • • • • • • • The PLL is off (asynchronous power-down). The VCO is off. The CLK input buffer is off. All dividers are off. All LVDS/CMOS outputs are off. All LVPECL outputs are in safe off mode. The serial control port is active, and the chip responds to commands. In synchronous power-down mode, the PLL power-down is gated by the charge pump to prevent unwanted frequency jumps. The device goes into power-down on the occurrence of the next charge pump event after the registers are updated. Distribution Power-Down The distribution section can be powered down by writing Register 0x230[1] = 1b. This turns off the bias to the distribution section. If the LVPECL power-down mode is normal operation (00b), it is possible for a low impedance load on that LVPECL output to draw significant current during this power-down. If the LVPECL power-down mode is set to 11b, the LVPECL output is not protected from reverse bias and may be damaged under certain termination conditions. Individual Clock Output Power-Down Any of the clock distribution outputs can be powered down individually by writing to the appropriate registers. The register map details the individual power-down settings for each output (see Table 52). The LVDS/CMOS outputs can be powered down, regardless of their output load configuration. If the AD9517 clock outputs must be synchronized to each other, a SYNC is required upon exiting power-down (see the Synchronizing the Outputs—Sync Function section). A VCO calibration is not required when exiting power-down. The LVPECL outputs have multiple power-down modes (see Table 56), which give some flexibility in dealing with the various output termination conditions. When the mode is set to 10b, the LVPECL output is protected from reverse bias to 2 VBE + 1 V. If the mode is set to 11b, the LVPECL output is not protected from reverse bias and can be damaged under certain termination conditions. This setting also affects the operation when the distribution block is powered down with Register 0x230[1] = 1b (see the Distribution Power-Down section). PLL Power-Down Individual Circuit Block Power-Down The PLL section of the AD9517 can be selectively powered down. There are three PLL operating modes set by Register 0x010[1:0], as shown in Table 54. Other AD9517 circuit blocks (such as CLK, REF1, and REF2) can be powered down individually. This gives flexibility in configuring the part for power savings whenever certain chip functions are not needed. Rev. E | Page 50 of 80 Data Sheet AD9517-4 SERIAL CONTROL PORT The AD9517 serial control port is a flexible, synchronous, serial communications port that allows an easy interface with many industry-standard microcontrollers and microprocessors. The AD9517 serial control port is compatible with most synchronous transfer formats, including both the Motorola SPI® and Intel® SSR® protocols. The serial control port allows read/write access to all registers that configure the AD9517. Single or multiple byte transfers are supported, as well as MSB first or LSB first transfer formats. The AD9517 serial control port can be configured for a single bidirectional I/O pin (SDIO only) or for two unidirectional I/O pins (SDIO/SDO). By default, the AD9517 is in bidirectional mode, long instruction (long instruction is the only instruction mode supported). SERIAL CONTROL PORT PIN DESCRIPTIONS SCLK (serial clock) is the serial shift clock. This pin is an input. SCLK is used to synchronize serial control port reads and writes. Write data bits are registered on the rising edge of this clock, and read data bits are registered on the falling edge. This pin is internally pulled down by a 30 kΩ resistor to ground. SDIO (serial data input/output) is a dual-purpose pin that acts as either an input only (unidirectional mode) or as both an input/output (bidirectional mode). The AD9517 defaults to the bidirectional I/O mode (Register 0x000[0] = 0b). SDO (serial data out) is used only in the unidirectional I/O mode (Register 0x000[0] = 1b) as a separate output pin for reading back data. CS (chip select bar) is an active low control that gates the read and write cycles. When CS is high, SDO and SDIO are in a high impedance state. This pin is internally pulled up by a 30 kΩ resistor to VS. 13 CS 14 SDO 15 SDIO 16 AD9517-4 SERIAL CONTROL PORT 06428-036 SCLK Figure 62. Serial Control Port GENERAL OPERATION OF SERIAL CONTROL PORT A write or a read operation to the AD9517 is initiated by pulling CS low. CS stalled high is supported in modes where three or fewer bytes of data (plus instruction data) are transferred (see Table 47). In these modes, CS can temporarily return high on any byte boundary, allowing time for the system controller to process the next byte. CS can go high on byte boundaries only and can go high during either part (instruction or data) of the transfer. During this period, the serial control port state machine enters a wait state until all data is sent. If the system controller decides to abort the transfer before all of the data is sent, the state machine must be reset, either by completing the remaining transfers or by returning CS low for at least one complete SCLK cycle (but less than eight SCLK cycles). Raising CS on a nonbyte boundary terminates the serial transfer and flushes the buffer. In the streaming mode (see Table 47), any number of data bytes can be transferred in a continuous stream. The register address is automatically incremented or decremented (see the MSB/LSB First Transfers section). CS must be raised at the end of the last byte to be transferred, thereby ending the stream mode. Communication Cycle—Instruction Plus Data There are two parts to a communication cycle with the AD9517. The first part writes a 16-bit instruction word into the AD9517, coincident with the first 16 SCLK rising edges. The instruction word provides the AD9517 serial control port with information regarding the data transfer, which is the second part of the communication cycle. The instruction word defines whether the upcoming data transfer is a read or a write, the number of bytes in the data transfer, and the starting register address for the first byte of the data transfer. Write If the instruction word is for a write operation, the second part is the transfer of data into the serial control port buffer of the AD9517. Data bits are registered on the rising edge of SCLK. The length of the transfer (1, 2, 3 bytes or streaming mode) is indicated by two bits ([W1:W0]) in the instruction byte. When the transfer is 1, 2, or 3 bytes, but not streaming, CS can be raised after each sequence of eight bits to stall the bus (except after the last byte, where it ends the cycle). When the bus is stalled, the serial transfer resumes when CS is lowered. Raising CS on a nonbyte boundary resets the serial control port. During a write, streaming mode does not skip over reserved or blank registers; therefore, the user must know the bit pattern to write to the reserved registers to preserve proper operation of the part. Refer to the control register map (see Table 52) to determine if the default value for reserved registers is nonzero. It does not matter what data is written to blank registers. Because data is written into a serial control port buffer area, and not directly into the actual control registers of the AD9517, an additional operation is needed to transfer the serial control port buffer contents to the actual control registers of the AD9517, thereby causing them to become active. The update registers operation consists of setting Register 0x232[0] = 1b (this bit is self-clearing). Any number of bytes of data can be changed before an update registers operation is executed. The update registers operation simultaneously actuates all register changes that have been written to the buffer since any previous update. Rev. E | Page 51 of 80 AD9517-4 Data Sheet Read If the instruction word is for a read operation, the next N × 8 SCLK cycles clock out the data from the address specified in the instruction word, where N is 1 to 3 as determined by [W1:W0]. If N = 4, the read operation is in streaming mode, continuing until CS is raised. Streaming mode does not skip over reserved or blank registers. The readback data is valid on the falling edge of SCLK. The default mode of the AD9517 serial control port is the bidirectional mode. In bidirectional mode, both the sent data and the readback data appear on the SDIO pin. It is also possible to set the AD9517 to unidirectional mode via the SDO active bit, Register 0x000[0] = 1b. In unidirectional mode, the readback data appears on the SDO pin. A readback request reads the data that is in the serial control port buffer area, or the data that is in the active registers (see Figure 63). Readback of the buffer or active registers is controlled by Register 0x004[0]. The AD9517 supports only the long instruction mode; therefore, Register 0x000[4:3] must be set to 11b. (This register uses mirrored bits.) Long instruction mode is the default at power-up or reset. SERIAL CONTROL PORT UPDATE REGISTERS WRITE REGISTER 0x232 = 0x01 TO UDATE REGISTERS 06428-037 CS ACTIVE REGISTERS SDO BUFFER REGISTERS SDIO Figure 63. Relationship Between Serial Control Port Buffer Registers and Active Registers of the AD9517 THE INSTRUCTION WORD (16 BITS) The MSB of the instruction word is R/W, which indicates whether the instruction is a read or a write. The next two bits, [W1:W0], indicate the length of the transfer in bytes. The final 13 bits are the address ([A12:A0]) at which to begin the read or write operation. For a write, the instruction word is followed by the number of bytes of data indicated by Bits[W1:W0] (see Table 47). Table 47. Byte Transfer Count W1 0 0 1 1 W0 0 1 0 1 Bytes to Transfer 1 2 3 Streaming mode MSB/LSB FIRST TRANSFERS The AD9517 instruction word and byte data can be MSB first or LSB first. Any data written to Register 0x000 must be mirrored; the upper four bits (Bits[7:4]) with the lower four bits (Bits[3:0). This makes it irrelevant whether LSB first or MSB first is in effect. As an example of this mirroring, see the default setting for this register: 0x18, which mirrors Bit 4 and Bit 3. This sets the long instruction mode (which is the default and the only mode that is supported). The default for the AD9517 is MSB first. When LSB first is set by Register 0x000[1] and Register 0x000[6], it takes effect immediately because it affects only the operation of the serial control port and does not require that an update be executed. When MSB first mode is active, the instruction and data bytes must be written from MSB to LSB. Multibyte data transfers in MSB first format start with an instruction byte that includes the register address of the most significant data byte. Subsequent data bytes must follow in order from the high address to the low address. In MSB first mode, the serial control port internal address generator decrements for each data byte of the multibyte transfer cycle. The AD9517 uses Register Address 0x000 to Register Address 0x232. SCLK The 13 bits found in [A12:A0] select the address within the register map that is written to or read from during the data transfer portion of the communications cycle. Only Bits[A9:A0] are needed to cover the range of the 0x232 registers used by the AD9517. Bits[A12:A10] must always be set to 0b. For multibyte transfers, this address is the starting byte address. In MSB first mode, subsequent bytes decrement the address. When LSB first is active, the instruction and data bytes must be written from LSB to MSB. Multibyte data transfers in LSB first format start with an instruction byte that includes the register address of the least significant data byte followed by multiple data bytes. The internal byte address generator of the serial control port increments for each byte of the multibyte transfer cycle. The AD9517 serial control port register address decrements from the register address just written toward 0x000 for multibyte I/O operations if the MSB first mode is active (default). If the LSB first mode is active, the register address of the serial control port increments from the address just written toward Address 0x232 for multibyte I/O operations. Streaming mode always terminates when it hits Address 0x232. Note that unused addresses are not skipped during multibyte I/O operations. Table 48. Streaming Mode (No Addresses Are Skipped) Write Mode LSB first MSB first Rev. E | Page 52 of 80 Address Direction Increment Decrement Stop Sequence 0x230, 0x231, 0x232, stop 0x001, 0x000, 0x232, stop Data Sheet AD9517-4 Table 49. Serial Control Port, 16-Bit Instruction Word, MSB First MSB I15 I14 I13 I12 I11 I10 I9 I8 I7 I6 I5 I4 I3 I2 I1 LSB I0 R/W W1 W0 A12 = 0 A11 = 0 A10 = 0 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0 CS SCLK DON'T CARE SDIO DON'T CARE R/W W1 W0 A12 A11 A10 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0 16-BIT INSTRUCTION HEADER D7 D6 D5 D4 D3 D2 D1 D0 D7 D6 D5 REGISTER (N) DATA D4 D3 D2 D1 D0 DON'T CARE REGISTER (N – 1) DATA 06428-038 DON'T CARE Figure 64. Serial Control Port Write—MSB First, 16-Bit Instruction, Two Bytes Data CS SCLK DON'T CARE SDIO DON'T CARE R/W W1 W0 A12 A11 A10 A9 A8 A7 A6 A5 A4 A3 A2 A1 A0 SDO DON'T CARE REGISTER (N) DATA REGISTER (N – 1) DATA REGISTER (N – 2) DATA REGISTER (N – 3) DATA DON'T CARE 06428-039 D7 D6 D5 D4 D3 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0 D7 D6 D5 D4 D3 D2 D1 D0 16-BIT INSTRUCTION HEADER Figure 65. Serial Control Port Read—MSB First, 16-Bit Instruction, Four Bytes Data tDS tS tHIGH tDH DON’T CARE SDIO DON’T CARE DON’T CARE R/W W1 W0 A12 A11 A10 A9 A8 A7 A6 A5 D4 D3 D2 D1 D0 DON’T CARE 06428-040 SCLK tC tCLK tLOW CS Figure 66. Serial Control Port Write—MSB First, 16-Bit Instruction, Timing Measurements CS SCLK DATA BIT N 06428-041 tDV SDIO SDO DATA BIT N – 1 Figure 67. Timing Diagram for Serial Control Port Register Read CS SCLK DON'T CARE DON'T CARE A0 A1 A2 A3 A4 A5 A6 A7 A8 A9 A10 A11 A12 W0 W1 R/W D0 D1 D2 D3 D4 16-BIT INSTRUCTION HEADER D5 D6 REGISTER (N) DATA D7 D0 D1 D2 D6 REGISTER (N + 1) DATA Figure 68. Serial Control Port Write—LSB First, 16-Bit Instruction, Two Bytes Data Rev. E | Page 53 of 80 D3 D4 D5 D7 DON'T CARE 06428-042 SDIO DON'T CARE AD9517-4 Data Sheet tS tC CS tCLK tHIGH SCLK tLOW tDS SDIO BIT N BIT N + 1 Figure 69. Serial Control Port Timing—Write Table 50. Serial Control Port Timing Parameter tDS tDH tCLK tS tC tHIGH tLOW tDV Description Setup time between data and rising edge of SCLK Hold time between data and rising edge of SCLK Period of the clock Setup time between CS falling edge and SCLK rising edge (start of communication cycle) Setup time between SCLK rising edge and CS rising edge (end of communication cycle) Minimum period that SCLK should be in a logic high state Minimum period that SCLK should be in a logic low state SCLK to valid SDIO and SDO (see Figure 67) Rev. E | Page 54 of 80 06428-043 tDH Data Sheet AD9517-4 THERMAL PERFORMANCE Table 51. Thermal Parameters for the 48-Lead LFCSP Symbol θJA θJMA θJMA θJB ΨJB ΨJB ΨJB θJC ΨJT ΨJT ΨJT Thermal Characteristic Using a JEDEC JESD51-7 Plus JEDEC JESD51-5 2S2P Test Board Junction-to-ambient thermal resistance, natural convection per JEDEC JESD51-2 (still air) Junction-to-ambient thermal resistance, 1.0 m/sec airflow per JEDEC JESD51-6 (moving air) Junction-to-ambient thermal resistance, 2.5 m/sec airflow per JEDEC JESD51-6 (moving air) Junction-to-board thermal resistance, natural convection per JEDEC JESD51-8 (still air) Junction-to-board characterization parameter, natural convection per JEDEC JESD51-6 (still air) and JEDEC JESD51-8 Junction-to-board characterization parameter, 1.0 m/sec airflow per JEDEC JESD51-6 (moving air) and JEDEC JESD51-8 Junction-to-board characterization parameter, 2.5 m/sec airflow per JEDEC JESD51-6 (moving air) and JEDEC JESD51-8 Junction-to-case thermal resistance (die-to-heat sink) per MIL-STD-883, Method 1012.1 Junction-to-top-of-package characterization parameter, natural convection per JEDEC JESD51-2 (still air) Junction-to-top-of-package characterization parameter, 1.0 m/sec airflow per JEDEC JESD51-2 (still air) Junction-to-top-of-package characterization parameter, 2.0 m/sec airflow per JEDEC JESD51-2 (still air) Value (°C/W) 24.7 21.6 19.4 12.9 11.9 11.8 11.6 1.3 0.1 0.2 0.3 Values of θJA are provided for package comparison and PCB design considerations. θJA can be used for a first-order approximation of TJ by the following equation Use the following equation to determine the junction temperature of the AD9517 on the application PCB: TJ = TCASE + (ΨJT × PD) where: TJ is the junction temperature (°C). TCASE is the case temperature (°C) measured by the user at the top center of the package. ΨJT is the value from Table 51. PD is the power dissipation of the device (see Table 17). TJ = TA + (θJA × PD) where TA is the ambient temperature (°C). Values of θJC are provided for package comparison and PCB design considerations when an external heat sink is required. Values of ΨJB are provided for package comparison and PCB design considerations. Rev. E | Page 55 of 80 AD9517-4 Data Sheet CONTROL REGISTERS CONTROL REGISTER MAP OVERVIEW Table 52. Control Register Map Overview Reg. Addr. (Hex) Parameter Bit 7 (MSB) Serial Port Configuration 0x000 Serial port SDO configuration active 0x001 0x002 0x003 Part ID 0x004 Readback control PLL 0x010 0x011 0x012 0x013 0x014 0x015 0x016 PFD and charge pump R counter A counter B counter PLL Control 1 0x017 0x018 PLL Control 2 PLL Control 3 0x019 PLL Control 4 0x01A PLL Control 5 0x01B PLL Control 6 0x01C PLL Control 7 0x01D PLL Control 8 0x01E 0x01F PLL Control 9 PLL readback 0x020 to 0x04F Bit 6 Bit 5 Bit 4 LSB first Soft reset Long Long instruction instruction Blank Reserved Part ID (read only) Blank PFD polarity Bit 3 Charge pump current Bit 2 Bit 1 Bit 0 (LSB) Default Value (Hex) Soft reset LSB first SDO active 0x18 Charge pump mode Read back active registers PLL power-down 14-bit R divider, Bits[7:0] (LSB) 14-bit R divider, Bits[13:8] (MSB) 6-bit A counter 13-bit B counter, Bits[7:0] (LSB) Blank 13-bit B counter, Bits[12:8] (MSB) Reset R Reset A and Reset all B counter Prescaler P Set CP pin counter B counters counters bypass to VCP/2 STATUS pin control Antibacklash pulse width Reserved Lock detect counter Digital lock Disable VCO calibration divider VCO cal now detect digital lock window detect R path delay N path delay R, A, B counters SYNC pin reset Reserved Reference LD pin control frequency monitor threshold REF1 (REFIN) REFMON pin control VCO REF2 frequency frequency (REFIN) monitor monitor frequency monitor Disable Select Use Reserved REF2 REF1 Differential switchover REF2 REF_SEL pin power-on power-on reference deglitch Holdover Holdover External LD pin Reserved PLL status enable enable holdover comparator register control enable disable Reserved Reserved VCO cal Holdover REF2 VCO REF2 REF1 Digital finished active selected frequency > frequency > frequency > lock detect threshold threshold threshold Blank Blank Blank Rev. E | Page 56 of 80 0xD3 0x00 0x7D 0x01 0x00 0x00 0x03 0x00 0x06 0x00 0x06 0x00 0x00 0x00 0x00 0x00 0x00 N/A Data Sheet AD9517-4 Reg. Addr. (Hex) Parameter Bit 7 (MSB) Bit 6 Fine Delay Adjust—OUT4 to OUT7 0x0A0 OUT4 delay bypass 0x0A1 OUT4 delay Blank full-scale 0x0A2 OUT4 delay Blank fraction 0x0A3 0x0A4 0x0A5 0x0A6 0x0A7 0x0A8 0x0A9 0x0AA 0x0AB OUT5 delay bypass OUT5 delay full-scale OUT5 delay fraction OUT6 delay bypass OUT6 delay full-scale OUT6 delay fraction OUT7 delay bypass OUT7 delay full-scale OUT7 delay fraction Blank Bit 3 Bit 2 Bit 1 Blank Bit 0 (LSB) OUT4 delay bypass OUT4 ramp current OUT4 ramp capacitors OUT4 delay fraction Blank OUT5 delay fraction Blank Blank Blank OUT6 delay fraction Blank Blank Blank OUT7 delay fraction 0x0F1 Blank 0x01 0x00 0x01 0x00 0x00 OUT7 delay bypass OUT7 ramp current OUT7 ramp capacitors 0x00 0x00 OUT6 delay bypass OUT6 ramp current OUT6 ramp capacitors 0x01 0x00 OUT5 delay bypass OUT5 ramp current OUT5 ramp capacitors Blank 0x01 0x00 0x00 Blank 0x0F2, 0x0F3 0x0F4 OUT2 Blank 0x0F5 OUT3 Blank OUT0 invert OUT1 invert OUT0 LVPECL differential voltage OUT1 LVPECL differential voltage OUT0 power-down 0x08 OUT1 power-down 0x0A OUT2 LVPECL differential voltage OUT3 LVPECL differential voltage OUT2 power-down 0x08 OUT3 power-down 0x0A Reserved 0x0F6 to 0x13F LVDS/CMOS Outputs 0x140 OUT4 OUT2 invert OUT3 invert Blank OUT4 CMOS output polarity 0x141 OUT5 OUT5 CMOS output polarity 0x142 OUT6 OUT6 CMOS output polarity 0x143 OUT7 OUT7 CMOS output polarity 0x144 to 0x18F Bit 4 Blank 0x0AC to 0x0EF LVPECL Outputs 0x0F0 OUT0 OUT1 Bit 5 Default Value (Hex) OUT4 LVDS/ CMOS output polarity OUT5 LVDS/ CMOS output polarity OUT6 LVDS/ CMOS output polarity OUT7 LVDS/ CMOS output polarity OUT4 CMOS B OUT4 select LVDS/CMOS OUT4 LVDS output current OUT4 power-down 0x42 OUT5 CMOS B OUT5 select LVDS/CMOS OUT5 LVDS output current OUT5 power-down 0x43 OUT6 CMOS B OUT6 select LVDS/CMOS OUT6 LVDS output current OUT6 power-down 0x42 OUT7 CMOS B OUT7 select LVDS/CMOS OUT7 LVDS output current OUT7 power-down 0x43 Blank Rev. E | Page 57 of 80 AD9517-4 Data Sheet Reg. Addr. (Hex) Parameter Bit 7 (MSB) LVPECL Channel Dividers 0x190 Divider 0 (PECL) 0x191 Divider 0 bypass 0x192 Blank 0x193 to 0x195 0x196 Bit 6 Bit 5 Bit 4 Bit 3 Divider 0 low cycles Divider 0 nosync Divider 0 force high Divider 0 start high Reserved Bit 2 Bit 1 Bit 0 (LSB) Default Value (Hex) Divider 0 high cycles 0x00 Divider 0 phase offset 0x80 Divider 0 direct to output Divider 0 DCCOFF 0x00 Reserved Divider1 (PECL) 0x197 Divider 1 low cycles Divider 1 bypass 0x198 Divider 1 nosync Blank Divider 1 force high Divider 1 start high Reserved Divider 1 high cycles 0x00 Divider 1 phase offset 0x00 Divider 1 direct to output Divider 1 DCCOFF 0x00 LVDS/CMOS Channel Dividers 0x199 Divider 2 (LVDS/CMOS) 0x19A 0x19B Low Cycles Divider 2.1 High Cycles Divider 2.1 0x22 Phase Offset Divider 2.2 Low Cycles Divider 2.2 Phase Offset Divider 2.1 High Cycles Divider 2.2 0x00 0x11 0x19C Reserved 0x19D Blank 0x19E Divider 3 (LVDS/CMOS) 0x19F 0x1A0 0x1A1 Reserved 0x1A2 0x1A3 0x1A4 to 0x1DF VCO Divider and CLK Input 0x1E0 VCO divider 0x1E1 Input CLKs Bypass Divider 2.2 Divider 2 nosync Reserved Divider 2 force high Start High Divider 2.2 Start High Divider 2.1 Divider 2 DCCOFF 0x00 0x00 Low Cycles Divider 3.1 High Cycles Divider 3.1 0x22 Phase Offset Divider 3.2 Low Cycles Divider 3.2 Bypass Divider 3.2 Phase Offset Divider 3.1 High Cycles Divider 3.2 Divider 3 Start High force high Divider 3.2 0x00 0x11 0x00 Bypass Divider 3.1 Blank Divider 3 nosync Reserved Start High Divider 3.1 Divider 3 DCCOFF 0x00 Reserved Blank Blank Reserved Power Power down down VCO clock clock input interface section Blank Reserved 0x1E2 to 0x22A System 0x230 Power-down and sync 0x231 Update All Registers 0x232 Update all registers Bypass Divider 2.1 Reserved Power down VCO and CLK Power down sync VCO Divider Select Bypass VCO VCO or CLK divider Power down distribution reference Reserved Blank Blank Rev. E | Page 58 of 80 Soft sync 0x02 0x00 0x00 0x00 Update all registers (selfclearing bit) 0x00 Data Sheet AD9517-4 CONTROL REGISTER MAP DESCRIPTIONS Table 53 through Table 62 provide a detailed description of each of the control register functions. The registers are listed by hexadecimal address. A range of bits (for example, from Bit 5 through Bit 2) is indicated using a colon and brackets, as follows: [5:2]. Table 53. Serial Port Configuration and Part ID Reg. Addr (Hex) 0x000 Bits [7:4] Name Mirrored, Bits[3:0] 3 Long instruction 2 Soft reset 1 LSB first 0 SDO active 0x003 [7:0] Part ID (read only) 0x004 0 Read back active registers Description Bits[7:4] should always mirror Bits[3:0] so that it does not matter whether the part is in MSB or LSB first mode (see Bit 1, Register 0x000). The user should set the bits as follows: Bit 7 = Bit 0. Bit 6 = Bit 1. Bit 5 = Bit 2. Bit 4 = Bit 3. Short/long instruction mode. This part uses long instruction mode only, so this bit should always be set to 1b. 0: 8-bit instruction (short). 1: 16-bit instruction (long) (default). Soft reset. 1: soft reset; restores default values to internal registers. Not self-clearing. Must be cleared to 0b to complete reset operation. MSB or LSB data orientation. 0: data-oriented MSB first; addressing decrements (default). 1: data-oriented LSB first; addressing increments. Selects unidirectional or bidirectional data transfer mode. 0: SDIO pin used for write and read; SDO set to high impedance; bidirectional mode (default). 1: SDO used for read, SDIO used for write; unidirectional mode. Uniquely identifies the dash version (-0 through -4) of the AD9517 AD9517-0: 0x11 AD9517-1: 0x51 AD9517-2: 0x91 AD9517-3: 0x53 AD9517-4: 0xD3 Selects register bank used for a readback. 0: reads back buffer registers (default). 1: reads back active registers. Rev. E | Page 59 of 80 AD9517-4 Data Sheet Table 54. PLL Reg. Addr. (Hex) 0x010 Bits 7 Name PFD polarity [6:4] CP current [3:2] CP mode [1:0] PLL power-down 0x011 [7:0] 0x012 [5:0] 0x013 0x014 [5:0] [7:0] 0x015 [4:0] 0x016 7 14-bit R divider, Bits[7:0] (LSB) 14-bit R divider, Bits[13:8] (MSB) 6-bit A counter 13-bit B counter, Bits[7:0] (LSB) 13-bit B counter, Bits[12:8] (MSB) Set CP pin to VCP/2 6 Reset R counter 5 Reset A, B counters 4 Reset all counters 3 B counter bypass Description Sets the PFD polarity. Negative polarity is for use (if needed) with external VCO/VCXO only. The on-chip VCO requires positive polarity; Bit 7 = 0b. 0: positive; higher control voltage produces higher frequency (default). 1: negative; higher control voltage produces lower frequency. Charge pump current (with CPRSET = 5.1 kΩ). 6 5 4 ICP (mA) 0 0 0 0.6 0 0 1 1.2 0 1 0 1.8 0 1 1 2.4 1 0 0 3.0 1 0 1 3.6 1 1 0 4.2 1 1 1 4.8 (default) Charge pump operating mode. 3 2 Charge Pump Mode 0 0 High impedance state. 0 1 Force source current (pump up). 1 0 Force sink current (pump down). 1 1 Normal operation (default). PLL operating mode. 1 0 Mode 0 0 Normal operation. 0 1 Asynchronous power-down (default). 1 0 Normal operation. 1 1 Synchronous power-down. R divider LSBs—lower eight bits (default = 0x01). R divider MSBs—upper six bits (default = 0x00). A counter (part of N divider) (default = 0x00). B counter (part of N divider)—lower eight bits (default = 0x03). B counter (part of N divider)—upper five bits (default = 0x00). Sets the CP pin to one-half of the VCP supply voltage. 0: CP normal operation (default). 1: CP pin set to VCP/2. Resets R counter (R divider). 0: normal (default). 1: holds the R counter in reset. Resets A and B counters (part of N divider). 0: normal (default). 1: holds the A and B counters in reset. Resets R, A, and B counters. 0: normal (default). 1: holds the R, A, and B counters in reset. B counter bypass. This is valid only when operating the prescaler in FD mode. 0: normal (default). 1: B counter is set to divide-by-1. This allows the prescaler setting to determine the divide for the N divider. Rev. E | Page 60 of 80 Data Sheet Reg. Addr. (Hex) 0x016 0x017 Bits [2:0] [7:2] Name Prescaler P STATUS pin control AD9517-4 Description Prescaler: DM = dual modulus and FD = fixed divide. 2 1 0 Mode Prescaler 0 0 0 FD Divide-by-1. 0 0 1 FD Divide-by-2. 0 1 0 DM Divide-by-2 (2/3 mode). 0 1 1 DM Divide-by-4 (4/5 mode). 1 0 0 DM Divide-by-8 (8/9 mode). 1 0 1 DM Divide-by-16 (16/17 mode). 1 1 0 DM Divide-by-32 (32/33 mode) (default). 1 1 1 FD Divide-by-3. Selects the signal that is connected to the STATUS pin. Level or Dynamic Signal Signal at STATUS Pin 7 6 5 4 3 2 0 0 0 0 0 0 LVL Ground (dc) (default). 0 0 0 0 0 1 DYN N divider output (after the delay). 0 0 0 0 1 0 DYN R divider output (after the delay). 0 0 0 0 1 1 DYN A divider output. 0 0 0 1 0 0 DYN Prescaler output. 0 0 0 1 0 1 DYN PFD up pulse. 0 0 0 1 1 0 DYN PFD down pulse. 0 X X X X X LVL Ground (dc); for all other cases of 0XXXXXb not specified above. The selections that follow are the same as REFMON. 1 0 0 0 0 0 LVL Ground (dc). 1 0 0 0 0 1 DYN REF1 clock (differential reference when in differential mode). 1 0 0 0 1 0 DYN REF2 clock (not available in differential mode). 1 0 0 0 1 1 DYN Selected reference to PLL (differential reference when in differential mode). 1 0 0 1 0 0 DYN Unselected reference to PLL (not available in differential mode). 1 0 0 1 0 1 LVL Status of selected reference (status of differential reference); active high. 1 0 0 1 1 0 LVL Status of unselected reference (not available in differential mode); active high. 1 0 0 1 1 1 LVL Status REF1 frequency (active high). 1 0 1 0 0 0 LVL Status REF2 frequency (active high). 1 0 1 0 0 1 LVL (Status REF1 frequency) AND (status REF2 frequency). 1 0 1 0 1 0 LVL (DLD) AND (status of selected reference) AND (status of VCO). 1 0 1 0 1 1 LVL Status of VCO frequency (active high). 1 0 1 1 0 0 LVL Selected reference (low = REF1, high = REF2). 1 0 1 1 0 1 LVL Digital lock detect (DLD); active high. 1 0 1 1 1 0 LVL Holdover active (active high). 1 0 1 1 1 1 LVL LD pin comparator output (active high). 1 1 0 0 0 0 LVL VS (PLL supply). 1 1 0 0 0 1 DYN REF1 clock (differential reference when in differential mode). 1 1 0 0 1 0 DYN REF2 clock (not available in differential mode). 1 1 0 0 1 1 DYN Selected reference to PLL (differential reference when in differential mode). 1 1 0 1 0 0 DYN 1 1 1 1 1 1 1 1 1 1 0 0 0 1 1 1 1 1 0 0 0 1 1 0 0 1 0 1 0 1 LVL LVL LVL LVL LVL Unselected reference to PLL (not available when in differential mode). Status of selected reference (status of differential reference); active low. Status of unselected reference (not available in differential mode); active low. Status of REF1 frequency (active low). Status of REF2 frequency (active low). 1 1 1 0 1 0 LVL (Status of REF1 frequency) AND (status of REF2 frequency). (DLD) AND (status of selected reference) AND (status of VCO). 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 0 0 1 1 1 0 1 0 1 LVL LVL LVL LVL LVL Status of VCO frequency (active low). Selected reference (low = REF2, high = REF1). Digital lock detect (DLD) (active low). Holdover active (active low). LD pin comparator output (active low). Rev. E | Page 61 of 80 AD9517-4 Data Sheet Reg. Addr. (Hex) 0x017 Bits [1:0] Name Antibacklash pulse width 0x018 [6:5] Lock detect counter 4 Digital lock detect window 3 Disable digital lock detect [2:1] VCO cal divider 0 VCO cal now [7:6] R, A, B counters SYNC pin reset [5:3] [2:0] R path delay N path delay 0x019 Description 1 0 Antibacklash Pulse Width (ns) 0 0 2.9 (default). This is the recommended setting; it does not normally need to be changed. 0 1 1.3. This setting may be necessary if the PFD frequency > 50 MHz. 1 0 6.0. 1 1 2.9. Required consecutive number of PFD cycles with edges inside lock detect window before the DLD indicates a locked condition. 6 5 PFD Cycles to Determine Lock 0 0 5 (default). 0 1 16. 1 0 64. 1 1 255. If the time difference of the rising edges at the inputs to the PFD is less than the lock detect window time, the digital lock detect flag is set. The flag remains set until the time difference is greater than the loss-of-lock threshold. 0: high range (default). 1: low range. Digital lock detect operation. 0: normal lock detect operation (default). 1: disables lock detect. VCO calibration divider. Divider used to generate the VCO calibration clock from the PLL reference clock. 2 1 VCO Calibration Clock Divider 0 0 2. This setting is fine for PFD frequencies < 12.5 MHz. The PFD frequency is fREF/R. 0 1 4. This setting is fine for PFD frequencies < 25 MHz. 1 0 8. This setting is fine for PFD frequencies < 50 MHz. 1 1 16 (default). This setting is fine for any PFD frequency but also results in the longest VCO calibration time. Bit used to initiate the VCO calibration. This bit must be toggled from 0b to 1b in the active registers. To initiate calibration, use the following three steps: first, ensure that the input reference signal is present; second, set to 0b (if not zero already), followed by an update bit (Register 0x232, Bit 0); and third, program to 1b, followed by another update bit (Register 0x232, Bit 0). Clearing this bit discards the VCO calibration and usually results in the PLL losing lock. The user must ensure that the holdover enable bits in Register 0x01D = 00b during VCO calibration. 7 6 Action 0 0 Does nothing on SYNC (default). 0 1 Asynchronous reset. 1 0 Synchronous reset. 1 1 Does nothing on SYNC. R path delay (default = 0x00) (see Table 2). N path delay (default = 0x00) (see Table 2). Rev. E | Page 62 of 80 Data Sheet Reg. Addr. (Hex) 0x01A Bits 6 Name Reference frequency monitor threshold [5:0] LD pin control AD9517-4 Description Sets the reference (REF1/REF2) frequency monitor’s detection threshold frequency. This does not affect the VCO frequency monitor’s detection threshold (see Table 16: REF1, REF2, and VCO frequency status monitor parameter). 0: frequency valid if frequency is above the higher frequency threshold (default). 1: frequency valid if frequency is above the lower frequency threshold. Selects the signal that is connected to the LD pin. Level or Dynamic Signal Signal at LD Pin 5 4 3 2 1 0 0 0 0 0 0 0 LVL Digital lock detect (high = lock, low = unlock) (default). 0 0 0 0 0 1 DYN P-channel, open-drain lock detect (analog lock detect). 0 0 0 0 1 0 DYN N-channel, open-drain lock detect (analog lock detect). 0 0 0 0 1 1 HIZ High-Z LD pin. 0 0 0 1 0 0 CUR Current source lock detect (110 µA when DLD is true). 0 X X X X X LVL Ground (dc); for all other cases of 0XXXXXb not specified above. The selections that follow are the same as REFMON. 1 0 0 0 0 0 LVL Ground (dc). 1 0 0 0 0 1 DYN REF1 clock (differential reference when in differential mode). 1 0 0 0 1 0 DYN REF2 clock (not available in differential mode). 1 0 0 0 1 1 DYN Selected reference to PLL (differential reference when indifferential mode). 1 0 0 1 0 0 DYN Unselected reference to PLL (not available in differential mode). 1 0 0 1 0 1 LVL Status of selected reference (status of differential reference); active high. 1 0 0 1 1 0 LVL Status of unselected reference (not available in differential mode); active high. 1 0 0 1 1 1 LVL Status REF1 frequency (active high). 1 0 1 0 0 0 LVL Status REF2 frequency (active high). 1 0 1 0 0 1 LVL (Status REF1 frequency) AND (status REF2 frequency). 1 0 1 0 1 0 LVL (DLD) AND (status of selected reference) AND (status of VCO). 1 0 1 0 1 1 LVL Status of VCO frequency (active high). 1 0 1 1 0 0 LVL Selected reference (low = REF1, high = REF2). 1 0 1 1 0 1 LVL Digital lock detect (DLD); active high. 1 0 1 1 1 0 LVL Holdover active (active high). 1 0 1 1 1 1 LVL Not available. Do not use. 1 1 0 0 0 0 LVL VS (PLL supply). 1 1 0 0 0 1 DYN REF1 clock (differential reference when in differential mode). 1 1 0 0 1 0 DYN REF2 clock (not available in differential mode). 1 1 0 0 1 1 DYN 1 1 0 1 0 0 DYN 1 1 0 1 0 1 LVL 1 1 0 1 1 0 LVL 1 1 1 1 1 1 0 1 1 1 0 0 1 0 0 1 0 1 LVL LVL LVL 1 1 1 0 1 0 LVL (DLD) AND (status of selected reference) AND (status of VCO). 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 0 1 1 1 1 1 0 0 1 1 1 0 1 0 1 LVL LVL LVL LVL LVL Status of VCO frequency (active low). Selected reference (low = REF2, high = REF1). Digital lock detect (DLD); active low. Holdover active (active low). Not available. Do not use. Selected reference to PLL (differential reference when in differential mode). Unselected reference to PLL (not available when in differential mode). Status of selected reference (status of differential reference); active low. Status of unselected reference (not available in differential mode); active low. Status of REF1 frequency (active low). Status of REF2 frequency (active low). (Status of REF1 frequency) AND (status of REF2 frequency). Rev. E | Page 63 of 80 AD9517-4 Reg. Addr. (Hex) 0x01B 0x01C Data Sheet Bits 7 Name VCO frequency monitor 6 REF2 (REFIN) frequency monitor 5 REF1 (REFIN) frequency monitor [4:0] REFMON pin control 7 6 Disable switchover deglitch Select REF2 5 Use REF_SEL pin [4:3] Reserved Description Enables or disables VCO frequency monitor. 0: disables VCO frequency monitor (default). 1: enables VCO frequency monitor. Enables or disables REF2 frequency monitor. 0: disables REF2 frequency monitor (default). 1: enables REF2 frequency monitor. REF1 (REFIN) frequency monitor enable; this is for both REF1 (single-ended) and REFIN (differential) inputs (as selected by differential reference mode). 0: disables REF1 (REFIN) frequency monitor (default). 1: enables REF1 (REFIN) frequency monitor. Selects the signal that is connected to the REFMON pin. Level or Dynamic Signal 4 3 2 1 0 Signal at REFMON Pin 0 0 0 0 0 LVL Ground (dc) (default). 0 0 0 0 1 DYN REF1 clock (differential reference when in differential mode). 0 0 0 1 0 DYN REF2 clock (not available in differential mode). 0 0 0 1 1 DYN Selected reference to PLL (differential reference when in differential mode). 0 0 1 0 0 DYN Unselected reference to PLL (not available in differential mode). 0 0 1 0 1 LVL Status of selected reference (status of differential reference); active high. 0 0 1 1 0 LVL Status of unselected reference (not available in differential mode); active high. 0 0 1 1 1 LVL Status REF1 frequency (active high). 0 1 0 0 0 LVL Status REF2 frequency (active high). 0 1 0 0 1 LVL (Status REF1 frequency) AND (status REF2 frequency). 0 1 0 1 0 LVL (DLD) AND (status of selected reference) AND (status of VCO). 0 1 0 1 1 LVL Status of VCO frequency (active high). 0 1 1 0 0 LVL Selected reference (low = REF1, high = REF2). 0 1 1 0 1 LVL Digital lock detect (DLD); active low. 0 1 1 1 0 LVL Holdover active (active high). 0 1 1 1 1 LVL LD pin comparator output (active high). 1 0 0 0 0 LVL VS (PLL supply). 1 0 0 0 1 DYN REF1 clock (differential reference when in differential mode). 1 0 0 1 0 DYN REF2 clock (not available in differential mode). 1 0 0 1 1 DYN Selected reference to PLL (differential reference when in differential mode). 1 0 1 0 0 DYN 1 1 1 1 1 0 0 0 1 1 1 1 1 0 0 0 1 1 0 0 1 0 1 0 1 LVL LVL LVL LVL LVL Unselected reference to PLL (not available in differential mode). Status of selected reference (status of differential reference); active low. Status of unselected reference (not available in differential mode); active low. Status of REF1 frequency (active low). Status of REF2 frequency (active low). (Status of REF1 frequency) AND (Status of REF2 frequency). 1 1 0 1 0 LVL (DLD) AND (Status of selected reference) AND (Status of VCO). 1 1 0 1 1 LVL Status of VCO frequency (active low). 1 1 1 0 0 LVL Selected reference (low = REF2, high = REF1). 1 1 1 0 1 LVL Digital lock detect (DLD); active low. 1 1 1 1 0 LVL Holdover active (active low). 1 1 1 1 1 LVL LD pin comparator output (active low). Disables or enables the switchover deglitch circuit. 0: enables switchover deglitch circuit (default). 1: disables switchover deglitch circuit. If Register 0x01C, Bit 5 = 0b, selects reference for PLL. 0: selects REF1 (default). 1: selects REF2. Sets method of PLL reference selection. 0: uses Register 0x01C, Bit 6 (default). 1: uses REF_SEL pin. Reserved (default: 00b). Rev. E | Page 64 of 80 Data Sheet Reg. Addr. (Hex) 0x01C 0x01D Bits 2 Name REF2 power-on 1 REF1 power-on 0 Differential reference 4 PLL status register disable 3 LD pin comparator enable 2 Holdover enable 1 External holdover control 0x01F 0 Holdover enable 6 VCO cal finished 5 Holdover active 4 REF2 selected 3 VCO frequency > threshold 2 REF2 frequency > threshold 1 REF1 frequency > threshold 0 Digital lock detect AD9517-4 Description This bit turns the REF2 power on. 0: REF2 power off (default). 1: REF2 power on. This bit turns the REF1 power on. 0: REF1 power off (default). 1: REF1 power on. Selects the PLL reference mode, differential or single-ended. Single-ended must be selected for the automatic switchover between REF1 and REF2 to work. 0: single-ended reference mode (default). 1: differential reference mode. Disables the PLL status register readback. 0: PLL status register enable (default). 1: PLL status register disable. Enables the LD pin voltage comparator. This function is used with the LD pin current source lock detect mode. When in the internal (automatic) holdover mode, this function enables the use of the voltage on the LD pin to determine if the PLL was previously in a locked state (see Figure 53). Otherwise, this function can be used with the REFMON and STATUS pins to monitor the voltage on this pin. 0: disables LD pin comparator; internal/automatic holdover controller treats this pin as true (high) (default). 1: enables LD pin comparator. Along with Bit 0, enables the holdover function. Automatic holdover must be disabled during VCO calibration. 0: holdover disabled (default). 1: holdover enabled. Enables the external hold control through the SYNC pin. (This disables the internal holdover mode.) 0: automatic holdover mode—holdover controlled by automatic holdover circuit. (default) 1: external holdover mode—holdover controlled by SYNC pin. Along with Bit 2, enables the holdover function. Automatic holdover must be disabled during VCO calibration. 0: holdover disabled (default). 1: holdover enabled. Read-only register: indicates status of the VCO calibration. 0: VCO calibration not finished. 1: VCO calibration finished. Read-only register: indicates if the part is in the holdover state (see Figure 53). This is not the same as holdover enabled. 0: not in holdover. 1: holdover state active. Read-only register: indicates which PLL reference is selected as the input to the PLL. 0: REF1 selected (or differential reference if in differential mode). 1: REF2 selected. Read-only register: indicates if the VCO frequency is greater than the threshold (see Table 16: REF1, REF2, and VCO frequency status monitor). 0: VCO frequency is less than the threshold. 1: VCO frequency is greater than the threshold. Read-only register: indicates if the frequency of the signal at REF2 is greater than the threshold frequency set by Register 0x1A, Bit 6. 0: REF2 frequency is less than threshold frequency. 1: REF2 frequency is greater than threshold frequency. Read-only register: indicates if the frequency of the signal at REF2 is greater than the threshold frequency set by Register 0x01A, Bit 6. 0: REF1 frequency is less than threshold frequency. 1: REF1 frequency is greater than threshold frequency. Read-only register: digital lock detect. 0: PLL is not locked. 1: PLL is locked. Rev. E | Page 65 of 80 AD9517-4 Data Sheet Table 55. Fine Delay Adjust—OUT4 to OUT7 Reg. Addr. (Hex) 0x0A0 Bits 0 Name OUT4 delay bypass 0x0A1 [5:3] OUT4 ramp capacitors [2:0] OUT4 ramp current 0x0A2 [5:0] OUT4 delay fraction 0x0A3 0 OUT5 delay bypass 0x0A4 [5:3] OUT5 ramp capacitors Description Bypasses or uses the delay function. 0: uses delay function. 1: bypasses delay function (default). Selects the number of ramp capacitors used by the delay function. The combination of the number of the capacitors and the ramp current sets the delay full scale. 5 4 3 Number of Capacitors 0 0 0 4 (default) 0 0 1 3 0 1 0 3 0 1 1 2 1 0 0 3 1 0 1 2 1 1 0 2 1 1 1 1 Ramp current for the delay function. The combination of the number of capacitors and the ramp current sets the delay full scale. 2 1 0 Current (µA) 0 0 0 200 (default) 0 0 1 400 0 1 0 600 0 1 1 800 1 0 0 1000 1 0 1 1200 1 1 0 1400 1 1 1 1600 Selects the fraction of the full-scale delay desired (6-bit binary). A setting of 000000b gives zero delay. Only delay values up to 47 decimals (101111b; 0x2F) are supported (default = 0x00). Bypasses or uses the delay function. 0: uses delay function. 1: bypasses delay function (default). Selects the number of ramp capacitors used by the delay function. The combination of the number of the capacitors and the ramp current sets the delay full scale. 5 4 3 Number of Capacitors 0 0 0 4 (default) 0 0 1 3 0 1 0 3 0 1 1 2 1 0 0 3 1 0 1 2 1 1 0 2 1 1 1 1 Rev. E | Page 66 of 80 Data Sheet Reg. Addr. (Hex) 0x0A4 Bits [2:0] Name OUT5 ramp current 0x0A5 [5:0] OUT5 delay fraction 0x0A6 0 OUT6 delay bypass 0x0A7 [5:3] OUT6 ramp capacitors [2:0] OUT6 ramp current 0x0A8 [5:0] OUT6 delay fraction 0x0A9 0 OUT7 delay bypass AD9517-4 Description Ramp current for the delay function. The combination of the number of capacitors and the ramp current sets the delay full scale. 2 1 0 Current (µA) 0 0 0 200 (default) 0 0 1 400 0 1 0 600 0 1 1 800 1 0 0 1000 1 0 1 1200 1 1 0 1400 1 1 1 1600 Selects the fraction of the full-scale delay desired (6-bit binary). A setting of 000000b gives zero delay. Only delay values up to 47 decimals (101111b; 0x2F) are supported (default = 0x00). Bypasses or uses the delay function. 0: uses delay function. 1: bypasses delay function (default). Selects the number of ramp capacitors used by the delay function. The combination of the number of capacitors and the ramp current sets the delay full scale. 5 4 3 Number of Capacitors 0 0 0 4 (default) 0 0 1 3 0 1 0 3 0 1 1 2 1 0 0 3 1 0 1 2 1 1 0 2 1 1 1 1 Ramp current for the delay function. The combination of the number of capacitors and the ramp current sets the delay full scale. 2 1 0 Current (µA) 0 0 0 200 (default) 0 0 1 400 0 1 0 600 0 1 1 800 1 0 0 1000 1 0 1 1200 1 1 0 1400 1 1 1 1600 Selects the fraction of the full-scale delay desired (6-bit binary). A setting of 000000b gives zero delay. Only delay values up to 47 decimals (101111b; 0x2F) are supported (default = 0x00). Bypasses or uses the delay function. 0: uses delay function. 1: bypasses delay function (default). Rev. E | Page 67 of 80 AD9517-4 Reg. Addr. (Hex) 0x0AA 0x0AB Data Sheet Bits [5:3] Name OUT7 ramp capacitors [2:0] OUT7 ramp current [5:0] OUT7 delay fraction Description Selects the number of ramp capacitors used by the delay function. The combination of the number of capacitors and the ramp current sets the delay full scale. 5 4 3 Number of Capacitors 0 0 0 4 (default) 0 0 1 3 0 1 0 3 0 1 1 2 1 0 0 3 1 0 1 2 1 1 0 2 1 1 1 1 Ramp current for the delay function. The combination of the number of capacitors and the ramp current sets the delay full scale. 2 1 0 Current Value (µA) 0 0 0 200 (default) 0 0 1 400 0 1 0 600 0 1 1 800 1 0 0 1000 1 0 1 1200 1 1 0 1400 1 1 1 1600 Selects the fraction of the full-scale delay desired (6-bit binary). A setting of 000000b gives zero delay. Only delay values up to 47 decimals (101111b; 0x2F) are supported (default = 0x00). Table 56. LVPECL Outputs Reg. Addr. (Hex) 0x0F0 Bits 4 Name OUT0 invert [3:2] OUT0 LVPECL differential voltage [1:0] OUT0 power-down Description Sets the output polarity. 0: noninverting (default). 1: inverting. Sets the LVPECL output differential voltage (VOD). 3 2 VOD (mV) 0 0 400 0 1 600 1 0 780 (default) 1 1 960 LVPECL power-down modes. 1 0 Mode 0 0 Normal operation (default). 0 1 Partial power-down, reference on; use only if there are no external load resistors. 1 0 Partial power-down, reference on, safe LVPECL power-down. 1 1 Total power-down, reference off; use only if there are no external load resistors. Rev. E | Page 68 of 80 Output On Off Off Off Data Sheet Reg. Addr. (Hex) 0x0F1 0x0F4 0x0F5 Bits 4 Name OUT1 invert [3:2] OUT1 LVPECL differential voltage [1:0] OUT1 power-down 4 OUT2 invert [3:2] OUT2 LVPECL differential voltage [1:0] OUT2 power-down 4 OUT3 invert [3:2] OUT3 LVPECL differential voltage [1:0] OUT3 power-down AD9517-4 Description Sets the output polarity. 0: noninverting (default). 1: inverting. Sets the LVPECL output differential voltage (VOD). 3 2 VOD (mV) 0 0 400 0 1 600 1 0 780 (default) 1 1 960 LVPECL power-down modes. 1 0 Mode 0 0 Normal operation. 0 1 Partial power-down, reference on; use only if there are no external load resistors. 1 0 Partial power-down, reference on, safe LVPECL power-down (default). 1 1 Total power-down, reference off; use only if there are no external load resistors. Sets the output polarity. 0: noninverting (default). 1: inverting. Sets the LVPECL output differential voltage (VOD). 3 2 VOD (mV) 0 0 400 0 1 600 1 0 780 (default) 1 1 960 LVPECL power-down modes. 1 0 Mode 0 0 Normal operation (default). 0 1 Partial power-down, reference on; use only if there are no external load resistors. 1 0 Partial power-down, reference on, safe LVPECL power-down. 1 1 Total power-down, reference off; use only if there are no external load resistors. Sets the output polarity. 0: noninverting (default). 1: inverting. Sets the LVPECL output differential voltage (VOD). 3 2 VOD (mV) 0 0 400 0 1 600 1 0 780 (default) 1 1 960 LVPECL power-down modes. 1 0 Mode 0 0 Normal operation. 0 1 Partial power-down, reference on; use only if there are no external load resistors. 1 0 Partial power-down, reference on, safe LVPECL power-down (default). 1 1 Total power-down, reference off; use only if there are no external load resistors. Rev. E | Page 69 of 80 Output On Off Off Off Output On Off Off Off Output On Off Off Off AD9517-4 Data Sheet Table 57. LVDS/CMOS Outputs Reg. Addr. (Hex) 0x140 0x141 Bits [7:5] Name OUT4 output polarity 4 OUT4 CMOS B 3 OUT4 select LVDS/CMOS [2:1] OUT4 LVDS output current 0 OUT4 power-down [7:5] OUT5 output polarity 4 OUT5 CMOS B 3 OUT5 select LVDS/CMOS [2:1] OUT5 LVDS output current Description In CMOS mode, Bits[7:5] select the output polarity of each CMOS output. In LVDS mode, only Bit 5 determines LVDS polarity. 7 6 5 OUT4A (CMOS) OUT4B (CMOS) OUT4 (LVDS) 0 0 0 Noninverting Inverting Noninverting 0 1 0 Noninverting Noninverting Noninverting (default) 1 0 0 Inverting Inverting Noninverting 1 1 0 Inverting Noninverting Noninverting 0 0 1 Inverting Noninverting Inverting 0 1 1 Inverting Inverting Inverting 1 0 1 Noninverting Noninverting Inverting 1 1 1 Noninverting Inverting Inverting In CMOS mode, turn on/off the CMOS B output. There is no effect in LVDS mode. 0: turns off the CMOS B output (default). 1: turns on the CMOS B output. Selects LVDS or CMOS logic levels. 0: LVDS (default). 1: CMOS. Sets output current level in LVDS mode. This has no effect in CMOS mode. 2 1 Current (mA) Recommended Termination (Ω) 0 0 1.75 100 0 1 3.5 100 (default) 1 0 5.25 50 1 1 7 50 Powers down output (LVDS/CMOS). 0: power on (default). 1: power off. In CMOS mode, Bits[7:5] select the output polarity of each CMOS output. In LVDS mode, only Bit 5 determines LVDS polarity. 7 6 5 OUT5A (CMOS) OUT5B (CMOS) OUT5 (LVDS) 0 0 0 Noninverting Inverting Noninverting 0 1 0 Noninverting Noninverting Noninverting (default) 1 0 0 Inverting Inverting Noninverting 1 1 0 Inverting Noninverting Noninverting 0 0 1 Inverting Noninverting Inverting 0 1 1 Inverting Inverting Inverting 1 0 1 Noninverting Noninverting Inverting 1 1 1 Noninverting Inverting Inverting In CMOS mode, turns on/off the CMOS B output. There is no effect in LVDS mode. 0: turns off the CMOS B output (default). 1: turns on the CMOS B output. Selects LVDS or CMOS logic levels. 0: LVDS (default). 1: CMOS. Sets output current level in LVDS mode. This has no effect in CMOS mode. 2 1 Current (mA) Recommended Termination (Ω) 0 0 1.75 100 0 1 3.5 100 (default) 1 0 5.25 50 1 1 7 50 Rev. E | Page 70 of 80 Data Sheet Reg. Addr. (Hex) 0x141 Bits 0 Name OUT5 power-down 0x142 [7:5] OUT6 output polarity 4 OUT6 CMOS B 3 OUT6 select LVDS/CMOS [2:1] OUT6 LVDS output current 0 OUT6 power-down [7:5] OUT7 output polarity 4 OUT7 CMOS B 3 OUT7 select LVDS/CMOS 0x143 AD9517-4 Description Powers down output (LVDS/CMOS). 0: power on. 1: power off (default). In CMOS mode, Bits[7:5] select the output polarity of each CMOS output. In LVDS mode, only Bit 5 determines LVDS polarity. 7 6 5 OUT6A (CMOS) OUT6B (CMOS) OUT6 (LVDS) 0 0 0 Noninverting Inverting Noninverting 0 1 0 Noninverting Noninverting Noninverting (default) 1 0 0 Inverting Inverting Noninverting 1 1 0 Inverting Noninverting Noninverting 0 0 1 Inverting Noninverting Inverting 0 1 1 Inverting Inverting Inverting 1 0 1 Noninverting Noninverting Inverting 1 1 1 Noninverting Inverting Inverting In CMOS mode, turns on/off the CMOS B output. There is no effect in LVDS mode. 0: turns off the CMOS B output (default). 1: turns on the CMOS B output. Selects LVDS or CMOS logic levels. 0: LVDS (default). 1: CMOS. Sets output current level in LVDS mode. This has no effect in CMOS mode. 2 1 Current (mA) Recommended Termination (Ω) 0 0 1.75 100 0 1 3.5 100 (default) 1 0 5.25 50 1 1 7 50 Powers down output (LVDS/CMOS). 0: power on (default). 1: power off. In CMOS mode, Bits[7:5] select the output polarity of each CMOS output. In LVDS mode, only Bit 5 determines LVDS polarity. 7 6 5 OUT7A (CMOS) OUT7B (CMOS) OUT7 (LVDS) 0 0 0 Noninverting Inverting Noninverting 0 1 0 Noninverting Noninverting Noninverting (default) 1 0 0 Inverting Inverting Noninverting 1 1 0 Inverting Noninverting Noninverting 0 0 1 Inverting Noninverting Inverting 0 1 1 Inverting Inverting Inverting 1 0 1 Noninverting Noninverting Inverting 1 1 1 Noninverting Inverting Inverting In CMOS mode, turns on/off the CMOS B output. There is no effect in LVDS mode. 0: turns off the CMOS B output (default). 1: turns on the CMOS B output. Selects LVDS or CMOS logic levels. 0: LVDS (default). 1: CMOS. Rev. E | Page 71 of 80 AD9517-4 Reg. Addr. (Hex) 0x143 Data Sheet Bits [2:1] Name OUT7 LVDS output current 0 OUT7 power-down Description Sets output current level in LVDS mode. This has no effect in CMOS mode. 2 1 Current (mA) Recommended Termination (Ω) 0 0 1.75 100 0 1 3.5 100 (default) 1 0 5.25 50 1 1 7 50 Powers down output (LVDS/CMOS). 0: power on. 1: power off (default). Table 58. LVPECL Channel Dividers Reg. Addr. (Hex) 0x190 0x191 0x192 0x196 0x197 Bits [7:4] Name Divider 0 low cycles [3:0] Divider 0 high cycles 7 Divider 0 bypass 6 Divider 0 nosync 5 Divider 0 force high 4 Divider 0 start high [3:0] 1 Divider 0 phase offset Divider 0 direct to output 0 Divider 0 DCCOFF [7:4] Divider 1 low cycles [3:0] Divider 1 high cycles 7 Divider 1 bypass 6 Divider 1 nosync 5 Divider 1 force high Description Number of clock cycles (minus 1) of the divider input during which divider output stays low. A value of 0x0 means that the divider is low for one input clock cycle (default = 0x0). Number of clock cycles (minus 1) of the divider input during which divider output stays high. A value of 0x0 means that the divider is high for one input clock cycle (default = 0x0). Bypasses and powers down the divider; routes input to divider output. 0: uses divider. 1: bypasses divider (default). No sync. 0: obeys chip-level SYNC signal (default). 1: ignores chip-level SYNC signal. Forces divider output to high. This requires that nosync (Bit 6) also be set. 0: divider output forced to low (default). 1: divider output forced to high. Selects clock output to start high or start low. 0: starts low (default). 1: starts high. Phase offset (default = 0x0). Connects OUT0 and OUT1 to Divider 0 or directly to VCO or CLK. 0: OUT0 and OUT1 are connected to Divider 0 (default). 1: If Register 0x1E1[1:0] = 10b, the VCO is routed directly to OUT0 and OUT1. If Register 0x1E1[1:0] = 00b, the CLK is routed directly to OUT0 and OUT1. If Register 0x1E1[1:0] = 01b, there is no effect. Duty-cycle correction function. 0: enables duty-cycle correction (default). 1: disables duty-cycle correction. Number of clock cycles of the divider input during which divider output stays low. A value of 0x0 means that the divider is low for one input clock cycle (default = 0x0). Number of clock cycles (minus 1) of the divider input during which divider output stays high. A value of 0x0 means that the divider is high for one input clock cycle (default = 0x0). Bypasses and powers down the divider; routes input to divider output. 0: uses divider (default). 1: bypasses divider. No sync. 0: obeys chip-level SYNC signal (default). 1: ignores chip-level SYNC signal. Forces divider output to high. This requires that nosync (Bit 6) also be set. 0: divider output forced to low (default). 1: divider output forced to high. Rev. E | Page 72 of 80 Data Sheet Reg. Addr. (Hex) 0x197 Bits 4 Name Divider 1 start high 0x198 [3:0] 1 Divider 1 phase offset Divider 1 direct to output 0 Divider 1 DCCOFF AD9517-4 Description Selects clock output to start high or start low. 0: starts low (default). 1: starts high. Phase offset (default = 0x0). Connects OUT2 and OUT3 to Divider 2 or directly to VCO or CLK. 0: OUT2 and OUT3 are connected to Divider 1 (default). 1: If Register 0x1E1[1:0] = 10b, the VCO is routed directly to OUT2 and OUT3. If Register 0x1E1[1:0] = 00b, the CLK is routed directly to OUT2 and OUT3. If Register 0x1E1[1:0] = 01b, there is no effect. Duty-cycle correction function. 0: enables duty-cycle correction (default). 1: disables duty-cycle correction. Table 59. LVDS/CMOS Channel Dividers Reg. Addr. (Hex) 0x199 Bits [7:4] Name Low Cycles Divider 2.1 [3:0] High Cycles Divider 2.1 0x19A [7:4] Phase Offset Divider 2.2 0x19B [3:0] [7:4] Phase Offset Divider 2.1 Low Cycles Divider 2.2 [3:0] High Cycles Divider 2.2 5 Bypass Divider 2.2 4 Bypass Divider 2.1 3 Divider 2 nosync 2 Divider 2 force high 1 Start High Divider 2.2 0 Start High Divider 2.1 0x19D 0 Divider 2 DCCOFF 0x19E [7:4] Low Cycles Divider 3.1 [3:0] High Cycles Divider 3.1 0x19C Description Number of clock cycles (minus 1) of 2.1 divider input during which 2.1 output stays low. A value of 0x0 means that the divider is low for one input clock cycle (default = 0x0). Number of clock cycles (minus 1) of 2.1 divider input during which 2.1 output stays high. A value of 0x0 means that the divider is high for one input clock cycle (default = 0x0). Refer to LVDS/CMOS channel divider function description (default = 0x0). Refer to LVDS/CMOS channel divider function description (default = 0x0). Number of clock cycles (minus 1) of 2.2 divider input during which 2.2 output stays low. A value of 0x0 means that the divider is low for one input clock cycle (default = 0x0). Number of clock cycles (minus 1)of 2.2 divider input during which 2.2 output stays high. A value of 0x0 means that the divider is high for one input clock cycle (default = 0x0). Bypasses (and powers down) 2.2 divider logic, routes clock to 2.2 output. 0: does not bypass (default). 1: bypasses. Bypasses (and powers down) 2.1 divider logic, routes clock to 2.1 output. 0: does not bypass (default). 1: bypasses. No sync. 0: obeys chip-level SYNC signal (default). 1: ignores chip-level SYNC signal. Forces Divider 2 output high. Requires that nosync also be set. 0: forces low (default). 1: forces high. Divider 2.2 start high/low. 0: starts low (default). 1: starts high. Divider 2.1 start high/low. 0: starts low (default). 1: starts high. Duty-cycle correction function. 0: enables duty-cycle correction (default). 1: disables duty-cycle correction. Number of clock cycles (minus 1) of 3.1 divider input during which 3.1 output stays low. A value of 0x0 means that the divider is low for one input clock cycle (default = 0x0). Number of clock cycles (minus 1) of 3.1 divider input during which 3.1 output stays high. A value of 0x0 means that the divider is high for one input clock cycle (default = 0x0). Rev. E | Page 73 of 80 AD9517-4 Reg. Addr. (Hex) 0x19F 0x1A0 0x1A1 0x1A2 Data Sheet Bits [7:4] [3:0] [7:4] Name Phase Offset Divider 3.2 Phase Offset Divider 3.1 Low Cycles Divider 3.2 [3:0] High Cycles Divider 3.2 5 Bypass Divider 3.2 4 Bypass Divider 3.1 3 Divider 3 nosync 2 Divider 3 force high 1 Start High Divider 3.2 0 Start High Divider 3.1 0 Divider 3 DCCOFF Description Refer to LVDS/CMOS channel divider function description (default = 0x0). Refer to LVDS/CMOS channel divider function description (default = 0x0). Number of clock cycles (minus 1) of 3.2 divider input during which 3.2 output stays low. A value of 0x0 means that the divider is low for one input clock cycle (default = 0x0). Number of clock cycles (minus 1) of 3.2 divider input during which 3.2 output stays high. A value of 0x0 means that the divider is high for one input clock cycle (default = 0x0). Bypasses (and powers down) 3.2 divider logic; routes clock to 3.2 output. 0: does not bypass (default). 1: bypasses. Bypasses (and powers down) 3.1 divider logic; routes clock to 3.1 output. 0: does not bypass (default). 1: bypasses. Nosync. 0: obeys chip-level SYNC signal (default). 1: ignores chip-level SYNC signal. Forces Divider 3 output high. Requires that nosync also be set. 0: forces low (default). 1: forces high. Divider 3.2 start high/low. 0: starts low (default). 1: starts high. Divider 3.1 start high/low. 0: starts low (default). 1: starts high. Duty-cycle correction function. 0: enables duty-cycle correction (default). 1: disables duty-cycle correction. Rev. E | Page 74 of 80 Data Sheet AD9517-4 Table 60. VCO Divider and CLK Input Reg. Addr (Hex) 0x1E0 Bits [2:0] Name VCO divider 0x1E1 4 Power down clock input section 3 Power down VCO clock interface 2 Power down VCO and CLK 1 Select VCO or CLK 0 Bypass VCO divider Description 2 1 0 0 0 0 0 0 1 0 1 0 0 1 1 1 0 0 1 0 1 Divide 2. 3. 4 (default). 5. 6. Output static. Note that setting the VCO divider static should occur only after VCO calibration. 1 1 0 Output static. Note that setting the VCO divider static should occur only after VCO calibration. 1 1 1 Output static. Note that setting the VCO divider static should occur only after VCO calibration. Powers down the clock input section (including CLK buffer, VCO divider, and CLK tree). 0: normal operation (default). 1: power-down. Powers down the interface block between VCO and clock distribution. 0: normal operation (default). 1: power-down. Powers down both VCO and CLK input. 0: normal operation (default). 1: power-down. Selects either the VCO or the CLK as the input to VCO divider. 0: selects external CLK as input to VCO divider (default). 1: selects VCO as input to VCO divider; cannot bypass VCO divider when this is selected. Bypasses or uses the VCO divider. 0: uses VCO divider (default). 1: bypasses VCO divider; cannot select VCO as input when this is selected. Table 61. System Reg. Addr. (Hex) 0x230 Bits 2 Name Power down sync 1 Power down distribution reference 0 Soft sync Description Powers down the sync function. 0: normal operation of the sync function (default). 1: powers down sync circuitry. Powers down the reference for distribution section. 0: normal operation of the reference for the distribution section (default). 1: powers down the reference for the distribution section. The soft sync bit works the same as the SYNC pin, except that the polarity of the bit is reversed. That is, a high level forces selected channels into a predetermined static state, and a 1-to-0 transition triggers a sync. 0: same as SYNC high (default). 1: same as SYNC low. Table 62. Update All Registers Reg. Addr (Hex) 0x232 Bits 0 Name Update all registers Description This bit must be set to 1b to transfer the contents of the buffer registers into the active registers. This bit is self-clearing; that is, it does not have to be set back to 0b. 1 (self-clearing): updates all active registers to the contents of the buffer registers. Rev. E | Page 75 of 80 AD9517-4 Data Sheet APPLICATIONS INFORMATION Within the AD9517 family, lower VCO frequencies generally result in slightly lower jitter. The difference in integrated jitter (from 12 kHz to 20 MHz offset) for the same output frequency is usually less than 150 fs over the entire VCO frequency range (1.45 GHz to 2.95 GHz) of the AD9517 family. If the desired frequency plan can be achieved with a version of the AD9517 that has a lower VCO frequency, choosing the lower frequency part results in the lowest phase noise and the lowest jitter. However, choosing a higher VCO frequency may result in more flexibility in frequency planning. Choosing a nominal charge pump current in the middle of the allowable range as a starting point allows the designer to increase or decrease the charge pump current, and thus allows the designer to fine-tune the PLL loop bandwidth in either direction. ADIsimCLK is a powerful PLL modeling tool that can be downloaded from www.analog.com. It is a very accurate tool for determining the optimal loop filter for a given application. USING THE AD9517 OUTPUTS FOR ADC CLOCK APPLICATIONS Any high speed ADC is extremely sensitive to the quality of its sampling clock. An ADC can be thought of as a sampling mixer, and any noise, distortion, or timing jitter on the clock is combined with the desired signal at the analog-to-digital output. Clock integrity requirements scale with the analog input frequency and resolution, with higher analog input frequency applications at ≥14-bit resolution being the most stringent. The theoretical SNR of an ADC is limited by the ADC resolution and the jitter where: fA is the highest analog frequency being digitized. tJ is the rms jitter on the sampling clock. Figure 70 shows the required sampling clock jitter as a function of the analog frequency and effective number of bits (ENOB). 110 18 1 SNR = 20log 2πf t A J 100 16 90 tJ = 100 fS 200 f 80 14 S 400 f 70 12 S 1ps 60 2ps 10 10p s 8 ENOB The AD9517 has the following four frequency dividers: the reference (or R) divider, the feedback (or N) divider, the VCO divider, and the channel divider. When trying to achieve a particularly difficult frequency divide ratio requiring a large amount of frequency division, some of the frequency division can be done by either the VCO divider or the channel divider, thus allowing a higher phase detector frequency and more flexibility in choosing the loop bandwidth. 1 SNR(dB) = 20 × log 2πf t A J 50 40 6 30 10 100 1k fA (MHz) 06428-044 The AD9517 is a highly flexible PLL. When choosing the PLL settings and version of the AD9517, keep in mind the following guidelines. on the sampling clock. Considering an ideal ADC of infinite resolution where the step size and quantization error can be ignored, the available SNR can be expressed approximately by SNR (dB) FREQUENCY PLANNING USING THE AD9517 Figure 70. SNR and ENOB vs. Analog Input Frequency See the AN-756 Application Note, Sampled Systems and the Effects of Clock Phase Noise and Jitter; and the AN-501 Application Note, Aperture Uncertainty and ADC System Performance, at www.analog.com. Many high performance ADCs feature differential clock inputs to simplify the task of providing the required low jitter clock on a noisy PCB. (Distributing a single-ended clock on a noisy PCB may result in coupled noise on the sample clock. Differential distribution has inherent common-mode rejection that can provide superior clock performance in a noisy environment.) The AD9517 features both LVPECL and LVDS outputs that provide differential clock outputs, which enable clock solutions that maximize converter SNR performance. The input requirements of the ADC (differential or single-ended, logic level, termination) should be considered when selecting the best clocking/converter solution. Rev. E | Page 76 of 80 Data Sheet AD9517-4 LVPECL CLOCK DISTRIBUTION The LVPECL outputs of the AD9517 provide the lowest jitter clock signals that are available from the AD9517. The LVPECL outputs (because they are open emitter) require a dc termination to bias the output transistors. The simplified equivalent circuit in Figure 59 shows the LVPECL output stage. In most applications, an LVPECL far-end Thevenin termination (see Figure 71) or Y-termination (see Figure 72) is recommended. In each case, the VS of the receiving buffer should match the VS_LVPECL voltage. If it does not, ac coupling is recommended (see Figure 73). In the case of Figure 73, pull-down resistors of <150 Ω are not recommended when VS_LVEPCL = 3.3 V; if used, damage to the LVPECL drivers may result. The minimum recommended pull-down resistor size for VS_LVPECL = 2.5 V is 100 Ω. The resistor network is designed to match the transmission line impedance (50 Ω) and the switching threshold (VS − 1.3 V). VS_DRV 50Ω LVPECL 127Ω 127Ω SINGLE-ENDED (NOT COUPLED) 50Ω VS LVPECL 83Ω 83Ω LVDS CLOCK DISTRIBUTION The AD9517 provides four clock outputs (OUT4 to OUT7) that are selectable as either CMOS or LVDS level outputs. LVDS is a differential output option that uses a current mode output stage. The nominal current is 3.5 mA, which yields 350 mV output swing across a 100 Ω resistor. An output current of 7 mA is also available in cases where a larger output swing is required. The LVDS output meets or exceeds all ANSI/TIA/EIA-644 specifications. Figure 71. DC-Coupled 3.3 V LVPECL Far-End Thevenin Termination VS_LVPECL VS = 3.3V LVPECL Z0 = 50Ω 50Ω A recommended termination circuit for the LVDS outputs is shown in Figure 74. 50Ω 50Ω LVPECL 06428-147 Z0 = 50Ω Thevenin-equivalent termination uses a resistor network to provide 50 Ω termination to a dc voltage that is below VOL of the LVPECL driver. In this case, VS_LVPECL on the AD9517 should equal VS of the receiving buffer. Although the resistor combination shown in Figure 72 results in a dc bias point of VS_LVPECL − 2 V, the actual common-mode voltage is VS_LVPECL − 1.3 V because additional current flows from the AD9517 LVPECL driver through the pull-down resistor. The circuit is identical when VS_LVPECL = 2.5 V, except that the pull-down resistor is 62.5 Ω and the pull-up resistor is 250 Ω. 06428-145 VS_LVPECL LVPECL Y-termination is an elegant termination scheme that uses the fewest components and offers both odd- and even-mode impedance matching. Even-mode impedance matching is an important consideration for closely coupled transmission lines at high frequencies. Its main drawback is that it offers limited flexibility for varying the drive strength of the emitter-follower LVPECL driver. This can be an important consideration when driving long trace lengths but is usually not an issue. In the case shown in Figure 72, where VS_LVPECL = 2.5 V, the 50 Ω termination resistor that is connected to ground should be changed to 19 Ω. Figure 72. DC-Coupled 3.3 V LVPECL Y-Termination VS 0.1nF 200Ω 100Ω DIFFERENTIAL 100Ω (COUPLED) 0.1nF TRANSMISSION LINE LVDS Figure 74. LVDS Output Termination See the AN-586 Application Note, LVDS Data Outputs for HighSpeed Analog-to-Digital Converters for more information on LVDS. LVPECL 200Ω 06428-146 LVPECL 100Ω 100Ω DIFFERENTIAL (COUPLED) 06428-047 LVDS VS_LVPECL VS VS Figure 73. AC-Coupled LVPECL with Parallel Transmission Line Rev. E | Page 77 of 80 AD9517-4 Data Sheet The AD9517 provides four clock outputs (OUT4 to OUT7) that are selectable as either CMOS or LVDS level outputs. When selected as CMOS, each output becomes a pair of CMOS outputs, each of which can be individually turned on or off and set as noninverting or inverting. These outputs are 3.3 V CMOS compatible. Whenever single-ended CMOS clocking is used, some of the following general guidelines should be used. Termination at the far end of the PCB trace is a second option. The CMOS outputs of the AD9517 do not supply enough current to provide a full voltage swing with a low impedance resistive, far-end termination, as shown in Figure 76. The far-end termination network should match the PCB trace impedance and provide the desired switching point. The reduced signal swing may still meet receiver input requirements in some applications. This can be useful when driving long trace lengths on less critical nets. VS Point-to-point nets should be designed such that a driver has only one receiver on the net, if possible. This allows for simple termination schemes and minimizes ringing due to possible mismatched impedances on the net. Series termination at the source is generally required to provide transmission line matching and/or to reduce current transients at the driver. The value of the resistor is dependent on the board design and timing requirements (typically 10 Ω to 100 Ω is used). CMOS outputs are also limited in terms of the capacitive load or trace length that they can drive. Typically, trace lengths of less than 3 inches are recommended to preserve signal rise/fall times and preserve signal integrity. 10Ω CMOS 50Ω 100Ω CMOS Figure 76. CMOS Output with Far-End Termination Because of the limitations of single-ended CMOS clocking, consider using differential outputs when driving high speed signals over long traces. The AD9517 offers both LVPECL and LVDS outputs that are better suited for driving long traces where the inherent noise immunity of differential signaling provides superior performance for clocking converters. 60.4Ω (1.0 INCH) MICROSTRIP 10Ω 100Ω 06428-076 CMOS CMOS 06428-077 CMOS CLOCK DISTRIBUTION Figure 75. Series Termination of CMOS Output Rev. E | Page 78 of 80 Data Sheet AD9517-4 OUTLINE DIMENSIONS 0.30 0.23 0.18 0.60 MAX 0.60 MAX 37 PIN 1 INDICATOR 6.85 6.75 SQ 6.65 1 0.50 REF *5.55 EXPOSED PAD 5.50 SQ 5.45 12 25 0.50 0.40 0.30 TOP VIEW 1.00 0.85 0.80 12° MAX 13 24 BOTTOMVIEW 0.22 MIN 5.50 REF 0.80 MAX 0.65 TYP 0.05 MAX 0.02 NOM COPLANARITY 0.08 0.20 REF SEATING PLANE PIN 1 INDICATOR 48 36 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-VKKD-2 WITH EXCEPTION TO EXPOSED PAD DIMENSION 06-06-2012-C 7.10 7.00 SQ 6.90 Figure 77. 48-Lead Lead Frame Chip Scale Package [LFCSP_VQ] 7 mm × 7 mm Body, Very Thin Quad CP-48-8 Dimensions shown in millimeters ORDERING GUIDE Model 1 AD9517-4ABCPZ AD9517-4ABCPZ-RL7 AD9517-4A/PCBZ 1 Temperature Range −40°C to +85°C −40°C to +85°C Package Description 48-Lead Lead Frame Chip Scale Package (LFCSP_VQ) 48-Lead Lead Frame Chip Scale Package (LFCSP_VQ) Evaluation Board Z = RoHS Compliant Part. Rev. E | Page 79 of 80 Package Option CP-48-8 CP-48-8 AD9517-4 Data Sheet NOTES ©2007–2013 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D06428-0-3/13(E) Rev. E | Page 80 of 80