LMK03000CEVAL/NOPB

LMK030xxC Evaluation Board User's Guide November 2013 SNAU040A LMK03000C/01C/02C/33C Precision Clock Conditioner with Integrated VCO Evaluation Board Operating Instructions April 2009 2 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 TABLE OF CONTENTS EQUIPMENT ..................................................................................................................................................................................5 BASIC OPERATION ........................................................................................................................................................................6 LMK03000C BOARD INFORMATION ............................................................................................................................................9 LOOP FILTER #1 ...........................................................................................................................................................................9 OSCin................................................................................................................................................... 10 Fout ...................................................................................................................................................... 10 Loop Filter ........................................................................................................................................... 10 Features of the board ............................................................................................................................ 11 Other Important Notes ......................................................................................................................... 11 Evaluation Board Revision v1.0 Errata ............................................................................................... 11 Results .................................................................................................................................................. 11 PHASE NOISE .............................................................................................................................................................................. 11 DELAYS ...................................................................................................................................................................................... 13 VCO PERFORMANCE .................................................................................................................................................................. 14 IMPACT OF REFERENCE ON PHASE NOISE ................................................................................................................................... 16 LMK03001C BOARD INFORMATION .......................................................................................................................................... 17 LOOP FILTER #1 ......................................................................................................................................................................... 17 OSCin................................................................................................................................................... 18 Fout ...................................................................................................................................................... 18 Loop Filter ........................................................................................................................................... 18 Features of the board ............................................................................................................................ 19 Other Important Notes ......................................................................................................................... 19 Evaluation Board Revision v1.0 Errata ............................................................................................... 19 Results .................................................................................................................................................. 19 PHASE NOISE .............................................................................................................................................................................. 19 DELAYS ...................................................................................................................................................................................... 21 VCO PERFORMANCE .................................................................................................................................................................. 22 IMPACT OF REFERENCE ON PHASE NOISE ................................................................................................................................... 24 LMK03002C BOARD INFORMATION .......................................................................................................................................... 25 LOOP FILTER #1 ......................................................................................................................................................................... 25 OSCin................................................................................................................................................... 26 Fout ...................................................................................................................................................... 26 Loop Filter ........................................................................................................................................... 26 Features of the board ............................................................................................................................ 27 Other Important Notes ......................................................................................................................... 27 Results .................................................................................................................................................. 27 PHASE NOISE .............................................................................................................................................................................. 27 DELAYS ...................................................................................................................................................................................... 29 VCO PERFORMANCE .................................................................................................................................................................. 30 Loop Filter #2 ...................................................................................................................................... 30 IMPACT OF REFERENCE ON PHASE NOISE ................................................................................................................................... 32 LMK03033C BOARD INFORMATION .......................................................................................................................................... 33 LOOP FILTER #1 ......................................................................................................................................................................... 33 OSCin................................................................................................................................................... 33 Fout ...................................................................................................................................................... 34 Loop Filter ........................................................................................................................................... 34 Features of the board ............................................................................................................................ 35 November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 3 Other Important Notes ......................................................................................................................... 35 Evaluation Board Revision v1.0 Errata ............................................................................................... 35 Results .................................................................................................................................................. 35 PHASE NOISE .............................................................................................................................................................................. 35 DELAYS ...................................................................................................................................................................................... 37 VCO PERFORMANCE .................................................................................................................................................................. 38 APPENDIX A: SCHEMATICS......................................................................................................................................................... 40 APPENDIX B: BILL OF MATERIALS ............................................................................................................................................. 43 APPENDIX C: BUILD DIAGRAM................................................................................................................................................... 45 APPENDIX D: QUICK START ON EVM COMMUNICATION .......................................................................................................... 47 4 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Equipment Power Supply The Power Supply should be a low noise power supply. An Agilent 6623A Triple power supply with LC filters on the output to reduce noise was used in creating these evaluation board instructions. Phase Noise / Spectrum Analyzer For measuring phase noise an Agilent E5052A is recommended. An Agilent E4445A PSA Spectrum Analyzer with the Phase Noise option is also usable although the architecture of the E5052A is superior for phase noise measurements. At frequencies less than 100 MHz the local oscillator noise of the PSA is too high and measurements will be of the local oscillator, not the device under test. Oscilloscope The oscilloscope and probes should be capable of measuring the output frequencies of interest when evaluating this board. The Agilent Infiniium DSO81204A was used in creating these evaluation board instructions. Reference Oscillator The on board crystal oscillator will provide a low noise reference signal to the device at offsets greater than 1 kHz. Note: The default loop filter has a loop bandwidth of ~60 kHz. Inside the loop bandwidth of a PLL the noise is greatly affected by any noise on the reference oscillator (OSCin). Therefore any noise on the oscillator less than 60 kHz will be passed through and seen on the outputs. For this reason the main output of a Signal Generator is not recommended for driving OSCin in this setup. November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 5 Basic Operation 1. Connect a low noise 3.3 V power supply to the Vcc connector located at the top left of the board. 2. Please see Appendix D for quick start on interfacing the board. Connect PC to the uWire header. 1 Power Supply 3.0 V Power Power Cable Cable Vcc 2 uWire header Please Please see see Appendix Appendix D D for for interface interface info info Laptop Laptop or or PC PC 6 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 3. Start CodeLoader4.exe. 4. Select the USB or LPT Communication Mode on the Port Setup tab as appropriate. 5. Enable output to be measured, any of CLKout(0-7) or EN_Fout from either Clock Outputs or Bits/Pins tab. In example below, CLKout0 is enabled. November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 7 Program Bits POWERDOWN EN_Fout OSCin_FREQ PLL_MUX DIV4 RESET VCO_R3_LF VCO_R4_LF VCO_C3_C4_LF EN_CLKout0..7 EN_CLKout_Global Program Pins GOE SYNC* TRIGGER Powers the part down. Turns on the Fout pin for measuring the internal VCO. Must be set to the OSCin frequency in MHz. Programmable to many different values to support Lock Detect or aid troubleshooting. Shall be checked for OSCin frequencies greater than 20 MHz. The registers can be defaulted by checking and unchecking RESET. Software bits will not reflect this. Internal loop filter values, also accessible from Clock Outputs tab. Enable CLKout bits from CLKout0 to CLKout7. Also accessible from Clock Outputs tab. Enable all clock outs. If unselected then the EN_CLKouts are overridden and the outputs are all disabled. Set Global Output Enable to high or low logic level. Set SYNC* pin to high or low logic level. Set auxiliary trigger pin to high or low logic level. 6. Program the part by clicking “Keyboard Controls”  “Load Device” OR by shortcut “Ctrl+L”. 7. Make measurements… After programming, the uWire cabling can be unplugged from the evaluation board to minimize noise and EMI. 8 SNAU040A LMK030xxC Evaluation Board User’s Guide November 2013 Copyright © 2013, Texas Instruments Incorporated www.ti.com LMK03000C Board information Loop Filter #1 Phase Margin 70.0º Loop Bandwidth 55.3 kHz fPD 9.72 MHz Crystal Frequency 19.44 MHz Output Frequency 1185 to 1296 MHz Supply Voltage 3.3 Volts VCO Gain 8 MHz/Volt 3200 uA Charge Pump R3 600  R4 200  VCO C2 12 nF C3 150 pF C4 110 pF R2 1.8 k C1 open CPout Loop filter #1 is selected by placing a 0 ohm resistor on pad R22. This loop filter has been designed for optimal RMS jitter using a low noise reference. November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 9 OSCin By default the board is configured to use the on-board crystal oscillator. It is also possible to use the board with a single ended or differential reference source at the OSCin port. Below are several possible configurations for driving OSCin. OSCin using on board crystal oscillator [default] 0 ohm R8, R11, R20 [power to crystal oscillator], R109 39 ohm R9 [can also be 0 ohm – depends on oscillator output power, 39 ohms to be a voltage divider] 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R7, R10, R12, R13, R14, R16, R17, R79, R112 Differential OSCin setup 0 ohm R7, R8, R10, R13 100 ohm R44 0.1 uF C5, C35 (C36 is a 0.1 uF 0402 cap which may be moved to C5) Open C4, C36 R11, R12, R14, R15, R16, R79 R20 [remove power from crystal oscillator for noise reasons] Single ended OSCin setup 0 ohm R7, R8 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R10, R11, R12, R13, R14, R16, R17, R79 R20 [remove power from crystal oscillator for noise reasons] Fout Fout allows direct access to the internal VCO before the clock distribution section. The EN_Fout bit must be selected to enable Fout. A 3 dB pad is placed on R80, R81, and R82. Loop Filter R22 and R5 form a “resistor switch” which allows either one of two different loop filters to be selected. Loop Filter Resistor Switch Loop Filter Components Default Loop Bandwidth Loop Filter #1 [default] R22 Shorted C1, C2, C2p, R2 59.1 kHz Loop Filter #2 R5 Shorted C1_AUX, C2_AUX, C2p_AUX, R2_AUX 77 Hz 10 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Features of the board     Either one of two loop filters can be selected by shorting either R22 or R5. More info about each loop filter can be found in the General Description and Appendix A. Test points for each of the uWire lines are scattered in the lower left corner of the board and include: GOE_TP, DATAuWire, CLKuWire, LEuWire, SYNC_TP, and LD_TP.  Ground is located on the unstuffed 10 pin header on the left side of the board. Ground is located on the GND_tp2 in the upper left corner of the board and GND_tp1 located to the right of the Vcc SMA connector. Ground is located on the bottom side of the board on each pad of the unstuffed 10 pin header GND_J2.    Vcc is located on the unstuffed 10 pin header on the upper left side of the board. Vcc is located on VccPlane test point located to the right of the Vcc SMA. Vcc is located on the bottom side of the board on each pad of the unstuffed 10 pin header VCC_J2 Other Important Notes    When changing the OSCin frequency, the OSCin frequency register needs to be changed to match. Toggle the SYNC* pin to synchronize the clock outputs when in divided mode. For both loop filters, a helper silkscreen is offset from the loop filters to help identify the components according to Texas Instruments Incorporated’s traditional reference designators associated with loop filters. Evaluation Board Revision v1.0 Errata  SYNC* is labeled on the PCB as SYNC, however the logic of SYNC* is still active low! Results November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 2.1 ps 100 Hz – 20 MHz integrated RMS jitter = 287 fs 12 kHz – 20 MHz integrated RMS jitter = 236 fs Output Frequency = 1244.16 MHz Internal VCO, Fout output Reference source is on board 19.44 MHz crystal Phase Noise 11 12 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 19.44 MHz crystal Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 1.8 ps 100 Hz – 20 MHz integrated RMS jitter = 315 fs 12 kHz – 20 MHz integrated RMS jitter = 256 fs (shown) Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 1.7 ps 100 Hz – 20 MHz integrated RMS jitter = 281 fs 12 kHz – 20 MHz integrated RMS jitter = 244 fs (shown) LVDS output CLKout0 VCO Frequency = 1244.16 MHz, VCO_DIV=2, CLKout0_div=4 LVDS output (155.52 MHz) Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 19.44 MHz crystal LVPECL output CLKout4 VCO Frequency = 1244.16 MHz, VCO_DIV=2, CLKout4_div=4 LVPECL output (155.52 MHz) Delays These delay measurements illustrate how skew errors due to different length traces may be tuned out. The delay may be adjusted in steps of 150 ps. Delays 150, 300, 450, 600, 750 CLKout0_DLY = 0 ps CLKout1_DLY = all delays programmed: 0, 150, 300, 450, 600, 750, 900, 1050, 1200, 1350, 1500, 1650, 1800, 1950, 2100, and 2250 ps November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 13 VCO Performance The internal VCO performance is measured by using a narrow bandwidth loop filter. By default the narrow loop bandwidth filter is stuffed as Loop Filter #2 in positions C1_AUX, C2_AUX, C2p_AUX, and R2_AUX and has a loop bandwidth of 77 Hz. See the Loop Filter section in Board Options for more detail about switching between the two different loop filters. Loop Filter Phase Margin 58.7º Loop Bandwidth 77 Hz fPD 1.023 MHz Crystal Frequency 19.44 MHz Output Frequency 1185 to 1296 MHz Supply Voltage 3.3 Volts VCO Gain 10 MHz/Volt 100 uA Charge Pump R3 600  R4 200  VCO C2 10 uF C3 150 pF C4 110 pF R2 820  C1 820 nF CPout This loop filter is located on the top side of the PCB and is selected by placing a 0 ohm resistor on pad R5. This loop filter has been designed with a very small loop bandwidth to minimize the PLL from interacting with the noise of the VCO to permit a VCO phase noise measurement. 14 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 VCO Phase Noise - Narrow Loop Bandwidth This plot shows the noise of the VCO at 1240 MHz using a 1 MHz Phase Detector Frequency. An external oscillator was used for this plot, since the VCO noise dominates, reference oscillator noise is not critical. The loop bandwidth has been minimized so that the VCO is the dominant noise contributor. 10 Hz – 20 MHz integrated RMS jitter = 56.9 ps (shown) 100 Hz – 20 MHz integrated RMS jitter = 25.0 ps 12 kHz – 20 MHz integrated RMS jitter = 0.304 ps (datasheet) November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 15 Impact of Reference on Phase Noise Inside the loop bandwidth of a PLL the phase noise is set by the quality of the reference oscillator used. For this reason it is important to select a reference oscillator suitable for the application. Test Setup Using the same loop filter as described in the General Description and by driving the OSCin frequency with an ultra low jitter 100 MHz Wetzel Crystal (501-04517D) and setting R = 10 to achieve a phase detector frequency of 10 MHz. A very low integrated RMS jitter of 247 fs is measured vs. the 2.1 ps measured in the Phase Noise section with 19.44 MHz crystal in the bandwidth of 10 Hz to 20 MHz. 10 Hz – 20 MHz integrated RMS jitter = 247 fs (shown) 100 Hz – 20 MHz integrated RMS jitter = 243 fs 12 kHz – 20 MHz integrated RMS jitter = 222 fs Conclusion This diagram illustrates how the phase noise inside the loop bandwidth is set by the quality of the reference oscillator used. Phase noise outside the loop bandwidth is set by the VCO noise level. 16 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 LMK03001C Board information Loop Filter #1 Phase Margin 74.4º Loop Bandwidth 59.1 kHz Fcomp 12.288 MHz Crystal Frequency 12.288 MHz Output Frequency 1470 to 1570 MHz Supply Voltage 3.3 Volts VCO Gain 10 MHz/Volt 3200 uA Charge Pump R3 100  R4 100  VCO C2 12 nF C3 100 pF C4 110 pF R2 1.8 k C1 open CPout Loop filter #1 is selected by placing a 0 ohm resistor on pad R22. This loop filter has been designed for optimal RMS jitter using a low noise reference. November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 17 OSCin By default the board is configured to use the on-board crystal oscillator. It is also possible to use the board with a single ended or differential reference source at the OSCin port. Below are several possible configurations for driving OSCin. OSCin using on board crystal oscillator [default] 0 ohm R8, R11, R20 [power to crystal oscillator], R109 39 ohm R9 [can also be 0 ohm – depends on oscillator output power, 39 ohms to be a voltage divider] 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R7, R10, R12, R13, R14, R16, R17, R79, R112 Differential OSCin setup 0 ohm R7, R8, R10, R13 100 ohm R44 0.1 uF C5, C35 (C36 is a 0.1 uF 0402 cap which may be moved to C5) Open C4, C36 R11, R12, R14, R15, R16, R79 R20 [remove power from crystal oscillator for noise reasons] Single ended OSCin setup 0 ohm R7, R8 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R10, R11, R12, R13, R14, R16, R17, R79 R20 [remove power from crystal oscillator for noise reasons] Fout Fout allows direct access to the internal VCO before the clock distribution section. The EN_Fout bit must be selected to enable Fout. A 3 dB pad is placed on R80, R81, and R82. Loop Filter R22 and R5 form a “resistor switch” which allows either one of two different loop filters to be selected. Loop Filter Resistor Switch Loop Filter Components Default Loop Bandwidth Loop Filter #1 [default] R22 Shorted C1, C2, C2p, R2 59.1 kHz Loop Filter #2 R5 Shorted C1_AUX, C2_AUX, C2p_AUX, R2_AUX 77 Hz 18 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Features of the board     Either one of two loop filters can be selected by shorting either R22 or R5. More info about each loop filter can be found in the General Description and Appendix A. Test points for each of the uWire lines are scattered in the lower left corner of the board and include: GOE_TP, DATAuWire, CLKuWire, LEuWire, SYNC_TP, and LD_TP.  Ground is located on the unstuffed 10 pin header on the left side of the board. Ground is located on the GND_tp2 in the upper left corner of the board and GND_tp1 located to the right of the Vcc SMA connector. Ground is located on the bottom side of the board on each pad of the unstuffed 10 pin header GND_J2.    Vcc is located on the unstuffed 10 pin header on the upper left side of the board. Vcc is located on VccPlane test point located to the right of the Vcc SMA. Vcc is located on the bottom side of the board on each pad of the unstuffed 10 pin header VCC_J2 Other Important Notes    When changing the OSCin frequency, the OSCin frequency register needs to be changed to match. Toggle the SYNC* pin to synchronize the clock outputs when in divided mode. For both loop filters, a helper silkscreen is offset from the loop filters to help identify the components according to Texas Instruments Incorporated’s traditional reference designators associated with loop filters. Evaluation Board Revision v1.0 Errata  SYNC* is labeled on the PCB as SYNC, however the logic of SYNC* is still active low! Results November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 782 fs 100 Hz – 20 MHz integrated RMS jitter = 269 fs 12 kHz – 20 MHz integrated RMS jitter = 238 fs Output Frequency = 1499.136 MHz Internal VCO, Fout output Reference source is on board 12.288 MHz crystal Phase Noise 19 20 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 12.288 MHz crystal Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 702 fs 100 Hz – 20 MHz integrated RMS jitter = 277 fs 12 kHz – 20 MHz integrated RMS jitter = 245 fs (shown) Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 679 fs 100 Hz – 20 MHz integrated RMS jitter = 278 fs 12 kHz – 20 MHz integrated RMS jitter = 248 fs (shown) LVDS output CLKout0 VCO Frequency = 1499.136 MHz, INPUT_DIV=2, CLKout0_div=4 LVDS output (187.392 MHz) Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 12.288 MHz crystal LVPECL output CLKout4 VCO Frequency = 1499.136 MHz, INPUT_DIV=2, CLKout4_div=4 LVPECL output (187.392 MHz) Delays These delay measurements illustrate how skew errors due to different length traces may be tuned out. The delay may be adjusted in steps of 150 ps. Delays 150, 300, 450, 600, 750 CLKout0_DLY = 0 ps CLKout1_DLY = all delays programmed: 0, 150, 300, 450, 600, 750, 900, 1050, 1200, 1350, 1500, 1650, 1800, 1950, 2100, and 2250 ps November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 21 VCO Performance The internal VCO performance is measured by using a narrow bandwidth loop filter. By default the narrow loop bandwidth filter is stuffed as Loop Filter #2 in positions C1_AUX, C2_AUX, C2p_AUX, and R2_AUX and has a loop bandwidth of 77 Hz. See the Loop Filter section in Board Options for more detail about switching between the two different loop filters. Loop Filter Phase Margin 58.7º Loop Bandwidth 77 Hz Fcomp 1.024 MHz Crystal Frequency 12.288 MHz Output Frequency 1470 to 1570 MHz Supply Voltage 3.3 Volts VCO Gain 10 MHz/Volt 100 uA Charge Pump R3 600  R4 200  VCO C2 10 uF C3 150 pF C4 110 pF R2 820  C1 820 nF CPout This loop filter is located on the top side of the PCB and is selected by placing a 0 ohm resistor on pad R5. This loop filter has been designed with a very small loop bandwidth to minimize the PLL from interacting with the noise of the VCO to permit a VCO phase noise measurement. 22 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 VCO Phase Noise - Narrow Loop Bandwidth This plot shows the noise of the VCO at 1500 MHz using a 1 MHz Phase Detector Frequency. An external oscillator was used for this plot, since the VCO noise dominates, reference oscillator noise is not critical. The loop bandwidth has been minimized so that the VCO is the dominant noise contributor. 10 Hz – 20 MHz integrated RMS jitter = 53.1 ps (shown) 100 Hz – 20 MHz integrated RMS jitter = 26.3 ps 12 kHz – 20 MHz integrated RMS jitter = 0.310 ps November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 23 Impact of Reference on Phase Noise Inside the loop bandwidth of a PLL the phase noise is set by the quality of the reference oscillator used. For this reason it is important to select a reference oscillator suitable for the application. Test Setup Using the same loop filter as described in the General Description and by driving the OSCin frequency with an ultra low jitter 100 MHz Wetzel Crystal (501-04517D) and setting R = 10 to achieve a phase detector frequency of 10 MHz. A very low integrated RMS jitter of 243 fs is measured vs. the 782 fs measured in the Phase Noise section with 12.288 MHz crystal in the bandwidth of 10 Hz to 20 MHz. 10 Hz – 20 MHz integrated RMS jitter = 243 fs (shown) 100 Hz – 20 MHz integrated RMS jitter = 240 fs 12 kHz – 20 MHz integrated RMS jitter = 220 fs Conclusion This diagram illustrates how the phase noise inside the loop bandwidth is set by the quality of the reference oscillator used. Phase noise outside the loop bandwidth is set by the VCO noise level. 24 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 LMK03002C Board information Loop Filter #1 Phase Margin 63º Loop Bandwidth 105 kHz Fcomp 16 MHz Crystal Frequency 16 MHz Output Frequency 1566 to 1724 MHz Supply Voltage 3.3 Volts VCO Gain 13 MHz/Volt 3200 uA Charge Pump R3 600  R4 200  VCO C2 12 nF C3 100 pF C4 110 pF R2 1.8 k C1 open CPout (Loop filter #1 is selected by placing a 0 ohm resistor on pad R22) November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 25 OSCin By default the board is configured to use the on-board crystal oscillator. It is also possible to use the board with a single ended or differential reference source at the OSCin port. Below are several possible configurations for driving OSCin. OSCin using on board crystal oscillator [default] 0 ohm R8, R11, R20 [power to crystal oscillator], R109 39 ohm R9 [can also be 0 ohm – depends on oscillator output power, 39 ohms to be a voltage divider] 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R7, R10, R12, R13, R14, R16, R17, R79, R112 Differential OSCin setup 0 ohm R7, R8, R10, R13 100 ohm R17 0.1 uF C5, C35 (C36 is a 0.1 uF 0402 cap which may be moved to C5) Open C4, C36 R11, R12, R14, R15, R16, R79 R20 [remove power from crystal oscillator for noise reasons] Single ended OSCin setup 0 ohm R7, R8 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R10, R11, R12, R13, R14, R16, R17, R79 R20 [remove power from crystal oscillator for noise reasons] Fout Fout allows direct access to the internal VCO before the clock distribution section. The EN_Fout bit must be selected to enable Fout. A 3 dB pad is placed on R80, R81, and R82. Loop Filter R22 and R5 form a “resistor switch” which allows either one of two different loop filters to be selected. Loop Filter Resistor Switch Loop Filter Components Default Loop Bandwidth Loop Filter #1 [default] R22 Shorted C1, C2, C2p, R2 105 kHz Loop Filter #2 R5 Shorted C1_AUX, C2_AUX, C2p_AUX, R2_AUX 55 Hz 26 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Features of the board     Either one of two loop filters can be selected by shorting either R22 or R5. More info about each loop filter can be found in the General Description and Appendix A. Test points for each of the uWire lines are scattered in the lower left corner of the board and include: GOE_TP, DATAuWire, CLKuWire, LEuWire, SYNC_TP, and LD_TP.  Ground is located on the unstuffed 10 pin header on the left side of the board. Ground is located on the GND_tp2 in the upper left corner of the board and GND_tp1 located to the right of the Vcc SMA connector. Ground is located on the bottom side of the board on each pad of the unstuffed 10 pin header GND_J2.    Vcc is located on the unstuffed 10 pin header on the upper left side of the board. Vcc is located on VccPlane test point located to the right of the Vcc SMA. Vcc is located on the bottom side of the board on each pad of the unstuffed 10 pin header VCC_J2 Other Important Notes    When changing the OSCin frequency, the OSCin frequency register needs to be changed to match. Toggle the SYNC* pin to synchronize the clock outputs when in divided mode. For both loop filters, a helper silkscreen is offset from the loop filters to help identify the components according to Texas Instruments Incorporated’s traditional reference designators associated with loop filters. Results November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 782 fs 100 Hz – 20 MHz integrated RMS jitter = 269 fs 12 kHz – 20 MHz integrated RMS jitter = 238 fs Output Frequency = 1499.136 MHz Internal VCO, Fout output Reference source is on board 12.288 MHz crystal Phase Noise 27 28 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 12.288 MHz crystal Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 702 fs 100 Hz – 20 MHz integrated RMS jitter = 277 fs 12 kHz – 20 MHz integrated RMS jitter = 245 fs (shown) Below ~1 kHz phase noise is dominated by the crystal 10 Hz – 20 MHz integrated RMS jitter = 679 fs 100 Hz – 20 MHz integrated RMS jitter = 278 fs 12 kHz – 20 MHz integrated RMS jitter = 248 fs (shown) LVDS output CLKout0 VCO Frequency = 1499.136 MHz, INPUT_DIV=2, CLKout0_div=4 LVDS output (187.392 MHz) Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 12.288 MHz crystal LVPECL output CLKout4 VCO Frequency = 1499.136 MHz, INPUT_DIV=2, CLKout4_div=4 LVPECL output (187.392 MHz) Delays These delay measurements illustrate how skew errors due to different length traces may be tuned out. The delay may be adjusted in steps of 150 ps. Delays 150, 300, 450, 600, 750 CLKout0_DLY = 0 ps CLKout1_DLY = all delays programmed: 0, 150, 300, 450, 600, 750, 900, 1050, 1200, 1350, 1500, 1650, 1800, 1950, 2100, and 2250 ps November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 29 VCO Performance The internal VCO performance is measured by using a narrow bandwidth loop filter. By default the narrow loop bandwidth filter is stuffed as Loop Filter #2 in positions C1_AUX, C2_AUX, C2p_AUX, and R2_AUX and has a loop bandwidth of 55 Hz. See the Loop Filter section in Board Options for more detail about switching between the two different loop filters. Loop Filter #2 Phase Margin 58º Loop Bandwidth 55 Hz Fcomp 500 kHz Crystal Frequency 16 MHz Output Frequency 1566 to 1724 MHz Supply Voltage 3.3 Volts VCO Gain 13 MHz/Volt 100 uA Charge Pump R3 600  R4 200  VCO C2 10 uF C3 150 pF C4 110 pF R2 820  C1 820 nF CPout This loop filter is located on the top side of the PCB and is selected by placing a 0 ohm resistor on pad R5. This loop filter has been designed with a very small loop bandwidth to minimize the PLL from interacting with the noise of the VCO to permit a VCO phase noise measurement. 30 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 VCO Phase Noise – Narrow Loop Bandwidth This plot shows the noise of the VCO at 1632 MHz using a 500 kHz Phase Detector Frequency. An external oscillator was used for this plot, since the VCO noise dominates, reference oscillator noise is not critical. The loop bandwidth has been minimized so that the VCO is the dominant noise contributor. 10 Hz – 20 MHz integrated RMS jitter = 107.6 ps 100 Hz – 20 MHz integrated RMS jitter = 28.1 ps (shown) 1 kHz – 20 MHz integrated RMS jitter = 2.7 ps 12 kHz – 20 MHz integrated RMS jitter = 0.303 ps November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 31 Impact of Reference on Phase Noise Inside the loop bandwidth of a PLL the phase noise is set by the quality of the reference oscillator used. For this reason it is important to select a reference oscillator suitable for the application. Test Setup Using the same loop filter as described in the General Description and by driving the OSCin frequency with an ultra low jitter 100 MHz Wetzel Crystal (501-04517D) and setting R = 5 to achieve a phase detector frequency of 20 MHz. A very low integrated RMS jitter of 201 fs is measured vs. the 474 fs measured in the Phase Noise section with 16 MHz crystal in the bandwidth of 10 Hz to 20 MHz. 10 Hz – 20 MHz integrated RMS jitter = 201 fs (shown) 100 Hz – 20 MHz integrated RMS jitter = 197 fs 1 kHz – 20 MHz integrated RMS jitter = 196 fs 12 kHz – 20 MHz integrated RMS jitter = 188 fs Conclusion This diagram illustrates how the phase noise inside the loop bandwidth is set by the quality of the reference oscillator used. Phase noise outside the loop bandwidth is set by the VCO noise level. 32 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 LMK03033C Board information Loop Filter #1 Phase Margin 63.5 deg Loop Bandwidth 104 kHz Fcomp 12.288 MHz Crystal Frequency 12.288 MHz Output Frequency 1843 to 2160 MHz Supply Voltage 3.3 Volts VCO Gain 20 MHz/Volt 3200 uA Charge Pump R3 600  R4 200  VCO C2 12 nF C3 150 pF C4 110 pF R2 1.8 k C1 open CPout OSCin By default the board is configured to use the on-board crystal oscillator. It is also possible to use the board with a single ended or differential reference source at the OSCin port. Below are several possible configurations for driving OSCin. OSCin using on board crystal oscillator [default] 0 ohm R8, R11, R20 [power to crystal oscillator], R109 39 ohm R9 [can also be 0 ohm – depends on oscillator output power, 39 ohms to be a voltage divider] 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R7, R10, R12, R13, R14, R16, R17, R79, R112 Differential OSCin setup 0 ohm R7, R8, R10, R13 November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 33 100 ohm 0.1 uF Open R44 C5, C35 (C36 is a 0.1 uF 0402 cap which may be moved to C5) C4, C36 R11, R12, R14, R15, R16, R79 R20 [remove power from crystal oscillator for noise reasons] Single ended OSCin setup 0 ohm R7, R8 51 ohm R15 0.1 uF C35, C36 (C5 is a 0.1 uF 0402 cap which may be moved to C36) Open C4, C5 R10, R11, R12, R13, R14, R16, R17, R79 R20 [remove power from crystal oscillator for noise reasons] Fout Fout allows direct access to the internal VCO before the clock distribution section. The EN_Fout bit must be selected to enable Fout. A 3 dB pad is placed on R80, R81, and R82. Loop Filter R22 and R5 form a “resistor switch” which allows either one of two different loop filters to be selected. Loop Filter Resistor Switch Loop Filter Components Loop Filter #1 [default] R22 Shorted C1, C2, C2p, R2 Loop Filter #2 R5 Shorted C1_AUX, C2_AUX, C2p_AUX, R2_AUX 34 SNAU040A Default Loop Bandwidth LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Features of the board     Either one of two loop filters can be selected by shorting either R22 or R5. More info about each loop filter can be found in the General Description and Appendix A. Test points for each of the uWire lines are scattered in the lower left corner of the board and include: GOE_TP, DATAuWire, CLKuWire, LEuWire, SYNC_TP, and LD_TP.  Ground is located on the unstuffed 10 pin header on the left side of the board. Ground is located on the GND_tp2 in the upper left corner of the board and GND_tp1 located to the right of the VCC SMA connector. Ground is located on the bottom side of the board on each pad of the unstuffed 10 pin header GND_J2.    VCC is located on the unstuffed 10 pin header on the upper left side of the board. VCC is located on VCCPlane test point located to the right of the VCC SMA. VCC is located on the bottom side of the board on each pad of the unstuffed 10 pin header VCC_J2 Other Important Notes    When changing the OSCin frequency, the OSCin frequency register needs to be changed to match. Toggle the SYNC* pin to synchronize the clock outputs when in divided mode. For both loop filters, a helper silkscreen is offset from the loop filters to help identify the components according to Texas Instruments Incorporated’s traditional reference designators associated with loop filters. Evaluation Board Revision v1.0 Errata  SYNC* is labeled on the PCB as SYNC, however the logic of SYNC* is still active low! Results November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 35 Below ~100 Hz phase noise is dominated by the crystal 100 Hz – 20 MHz integrated RMS jitter = 256 fs 12 kHz – 20 MHz integrated RMS jitter = 239 fs (shown) Output Frequency = 1966.08 MHz Internal VCO, Fout output Reference source is on board 12.288 MHz crystal Phase Noise 36 SNAU040A LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com November 2013 Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 12.288 MHz crystal Below ~100 Hz phase noise is dominated by the crystal 100 Hz – 20 MHz integrated RMS jitter = 261 fs 12 kHz – 20 MHz integrated RMS jitter = 244 fs (shown) Below ~100 Hz phase noise is dominated by the crystal 100 Hz – 20 MHz integrated RMS jitter = 265 fs 12 kHz – 20 MHz integrated RMS jitter = 248 fs (shown) LVDS output CLKout0 VCO Frequency = 1966.08 MHz, VCO_DIV=2, CLKout0_div=4 LVDS output (245.76 MHz) Output is measured with a Minicircuits ADT2-1T balun. Reference source is on board 12.288 MHz crystal LVPECL output CLKout4 VCO Frequency = 1966.08 MHz, VCO_DIV=2, CLKout4_div=4 LVPECL output (245.76 MHz) Delays These delay measurements illustrate how skew errors due to different length traces may be tuned out. The delay may be adjusted in steps of 150 ps. Delays 150, 300, 450, 600, 750 CLKout0_DLY = 0 ps CLKout1_DLY = all delays programmed: 0, 150, 300, 450, 600, 750, 900, 1050, 1200, 1350, 1500, 1650, 1800, 1950, 2100, and 2250 ps November 2013 LMK030xxC Evaluation Board User’s Guide Copyright © 2013, Texas Instruments Incorporated www.ti.com SNAU040A 37 VCO Performance The internal VCO performance is measured by using a narrow bandwidth loop filter. By default the narrow loop bandwidth filter is stuffed as Loop Filter #2 in positions C1_AUX, C2_AUX, C2p_AUX, and R2_AUX and has a narrow loop bandwidth. See the Loop Filter section in Board Options for more detail about switching between the two different loop filters. Loop Filter Phase Margin 100 uA Loop Bandwidth