TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 HIGH-PERFORMANCE INTEGER-N PLL FREQUENCY SYNTHESIZER D D Lock Detect Output (Digital and Analog) D Versatile Hardware and Software Power Down D Packaged in a 16-Pin TSSOP Thin Quad FlatPack and a 20-Pin 4 x 4 mm QFN Package APPLICATIONS D Wireless Infrastructure PW PACKAGE (TOP VIEW) RSET CPOUT CPGND AGND RFIN RFIN AVDD REFIN DESCRIPTION The TRF3750 frequency synthesizer is ideal for designing the local os cillator portion of wireless transceivers by providing complete programmability and ultra-low phase noise. The device features a user-selectable dualmodulus prescaler, a 14-bit reference (R) divider, a 6-bit A, 16 15 14 13 12 11 10 9 VCP DVDD MUXOUT LE DATA CLOCK CE DGND RGP PACKAGE (TOP VIEW) CPOUT RSET VCP DVDD DVDD − GSM, IS136, EDGE/UWC−136 − IS95, UMTS, CDMA2000 Portable Wireless Communications Wireless LAN D D D Wireless Transceivers D Communication Test Equipment 1 2 3 4 5 6 7 8 CPGND 1 20 19 18 17 16 15 AGND AGND RFIN 2 14 3 13 4 12 RFIN 5 6 7 8 9 11 10 MUXOUT LE DATA CLOCK CE DGND D AVDD REFIN DGND D 2.4 GHz Dual Supply Range: 3 V − 3.6 V and 4.5 V − 5.5 V Separate Charge Pump Supply (VCP) Up to 8 V Simple 3-Wire Serial Interface Allows for Fully Programmable: − A, B, and R Counters − Dual Modulus Prescaler [8/9, 16/17, 32/33, and 64/65] − Charge Pump Current and a 13-bit B counter. The R divider allows the user to select the frequency of choice for the phase-frequency detector (PFD) circuit, and with the use of the counters implement an N divider of value N = A + P x B. With an extended charge-pump supply (VCP) of up to 8 V, a wide variety of external VCOs can be used to complete the phase-locked loop. Ultra-low phase noise and reference spur performance make the TRF3750 ideal for generating the local oscillator in the most demanding wireless applications. AVDD FEATURES D Single Device Covers Frequencies Up to Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright 2004, Texas Instruments Incorporated TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. FUNCTIONAL BLOCK DIAGRAM FOR TSSOP PACKAGE DVDD AVDD 15 VCP 7 16 Bias PFD REFIN CLOCK DATA LE CE Charge Pump 2 RSET CPOUT 14 11 24-Bit Data Shift Register 12 13 10 1 14-Bit R Counter 8 Power Down Function Latch Current Setting 2 22 N Counter Latch 22 Initialization Latch Current Setting 1 R Counter Latch 22 22 Lock Detect 19 N Divider 6 RFIN RFIN 6 5 13 6-Bit A Counter Prescaler P/P+1 13-Bit B Counter LD LD MUX DVDD 4 AGND 2 9 DGND 3 CPGND 14 MUXOUT TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 ORDERING INFORMATION PRODUCT PACKAGE / LEADS PACKAGE DESIGNATOR SPECIFIED TEMPERATURE RANGE PACKAGE MARKING ORDERING NUMBER TRANSPORT MEDIA QUANTITY TRF3750IPW TSSOP-16 PW –40°C to 85°C TRF3750 TRF3750IPW Tube 90 TRF3750IPWR TSSOP-16 PW –40°C to 85°C TRF3750 TRF3750IPWR Reel 2000 TRF3750IRGP QFN-20 RGP –40°C to 85°C TRF3750 TRF3750IRGP Tube 91 TRF3750IRGPR QFN-20 RGP –40°C to 85°C TRF3750 TRF3750IRGPR Reel 1000 PIN ASSIGNMENTS TERMINAL NAME RSET QFN(1) NO. TSSOP NO. TYPE 19 1 O DESCRIPTION The user needs to place an external resistor (RSET) from this pin to ground to control the maximum charge pump current. This node’s output voltage is typically around 1 V and the relationship between ICPOUTmax and RSET is: + 23.5 RSET A 4.7-kΩ resistor placed at this pin to ground would hence provide a maximum charge pump output current of approximately 5 mA. I CPOUT CPOUTmax 20 2 O Charge pump output. This node provides the charge pump current that ultimately controls the external VCO. CPGND 1 3 I Charge pump ground AGND 23 4 I Analog ground RFIN 4 5 I Complementary input to the prescaler. For single-ended applications, bypass with a small capacitor to ground (typically 100 pF). RFIN 5 6 I Input to the prescaler. To complete the PLL, this signal must come from the output of the external VCO. AVDD 6, 7 7 I Analog power supply. There are two possible supply ranges: 3 V − 3.6 V and 4.5 V − 5.5 V. This value should be the same as the DVDD. Appropriate decoupling is necessary for optimal performance. REFIN 8 8 I Reference frequency input. This externally provided reference gets divided by the selectable R divider, and is used to synthesize the desired output frequency. Typically this input is an ac-coupled sinusoid; however, a TTL or CMOS signal can also be used. DGND 9, 10 9 I Digital ground CE 11 10 I Chip enable. Setting this pin low puts the device into power down; setting it high activates the charge pump if the software controlled power down is also disabled. CLOCK 12 11 I Serial clock input. This is the input that is used to clock the serial data into the 24-bit shift register of the device. The data is read at the rising edge of this clock. DATA 13 12 I Serial data input. This is the data stream that contains the data to be loaded into the shift register. The data is loaded MSB first. LE 14 13 I Load enable. When this asynchronous signal is asserted high, the data existing in the shift register get loaded onto the selected latch. MUXOUT 15 14 O This user-selectable output can be controlled to provide the digital or analog lock detect signals, the divide by N RF signal or the divide by R reference. The output can also be 3-stated. 16, 17 15 I Digital power supply. There are two possible supply ranges: 3 V − 3.6 V and 4.5 V − 5.5 V. This value should be the same as the AVDD. Appropriate decoupling is necessary for optimal performance. 18 16 I Charge pump supply. This supply must be at least 1 V greater than the AVDD and DVDD and can be as high as 8 V, accommodating a large range of possible VCOs. DVDD VCP (1) The thermal pad on the bottom of the QFN package may be tied to ground, but is not required to meet specified performance. 3 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 ABSOLUTE MAXIMUM RATINGS over operating free-air temperature range unless otherwise noted(1) UNIT Supply voltage range(2) AVDD −0.3 V to 6.5 V AVDD to DVDD −0.3 V to 0.3 V VCP to AGND −0.3 V to 9 V Digital I/O voltage to DGND (DGND = 0 V) −0.3 V to 6.5 V Reference signal input REFIN to DGND RF prescaler input RFIN, RFIN to AGND −0.3 V to DVDD + 0.3 V −0.3 V to 6.5 V Continuous power dissipation See Dissipation Rating Table Storage temperature, TStg −65°C to 150°C Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds 260°C (1) Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. (2) All voltage values are with respect to network ground terminal. DISSIPATION RATING TABLE (1) PACKAGE TA ≤ 25°C DERATING FACTOR(1) ABOVE TA = 25°C TA = 85°C POWER RATING 16-pin TSSOP 2780 mW 22.2 mW/_C 1440 mW 20-pin QFN 2780 mW 29 mW/_C 1440 mW This is the inverse of the junction-to-ambient thermal resistance when board mounted and with no airflow. RECOMMENDED OPERATING CONDITIONS AVDD = DVDD, 3.3 V range Supply voltage AVDD = DVDD, 5 V range VCP High−level input voltage, VIH Low−level input voltage, VIL High−level output voltage, VOH Low−level output voltage, VOL Operating free-air temperature, TA 4 LE DATA LE, DATA, CLK CLK, CE MUXOUT MIN NOM MAX 3 3.3 3.6 V 4.5 5 5.5 V 8 V (AVDD, DVDD) + 1 0.8 x DVDD V 0.2 x DVDD DVDD − 0.4 −40 UNIT V V 0.4 V 85 °C TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 ELECTRICAL CHARACTERISTICS Conditions: (AVDD = DVDD = 3.3 V or 5 V, AVDD + 1≤ VCP ≤ 8 V, RSET = 4.7 kΩ, TA = −40°C to 85°C, REFIN = 10 MHz at +5 dBm) (unless otherwise stated) PARAMETER IAVDD Supply current IDVDD Supply current IVCP Supply current TEST CONDITIONS MIN TYP AVDD = 3.3 V 10 AVDD = 5 V 13 DVDD = 3.3 V 3.5 VCP = 7 V 7.5 RFIN input frequency (RF input) RF prescaler output frequency −15 (1) REFIN input frequency (reference input) (1) 4 REFIN input power level sensitivity Charge pump max source current ICPOUTmin Charge pump max sink current VTUNE (1) (2) Output tuning voltage (2) mA 2400 MHz +5 dBm 200 MHz 350 MHz dBm 5 PFD maximum frequency (1) ICPOUTmax mA −10 REFIN input capacitance pF 60 Measured at the output of the external loop filter, in locked condition 1 UNIT mA 3 DVDD = 5 V RFIN input power level MAX MHz 5 mA −5 mA VCP−1.1 V Assured by design. VTUNE range shown is for optimal spurious performance; the device can function beyond these limits. 5 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 ELECTRICAL CHARACTERISTICS Conditions (unless otherwise stated): AVDD = DVDD = 3.3 V or 5 V, VCP = 7 V; RSET = 4.7 kΩ, TA = 27°C, REFIN = 10 MHz at 6.5 dBm Referenced to 50 Ω, ICPOUTmax = 5 mA, Power Down: Normal Operation; Timer Counter Control: Not used; MUXOUT Control: 3-state; Fast Lock Mode: Disabled, PFD Polarity: Positive, Anti-backlash Pulse width: 1.5 ns, Resync/Delay: Normal (Delay=0, Resync=0), Counter Operation: Normal, Charge Pump Output: Normal, Lock Detect Precision: 5 cycles PARAMETER Phase noise 110 MHz) Reference spurs 110 MHz Phase noise 300 MHz Reference spurs 300 MHz Phase noise 540 MHz Reference spurs 540 MHz Phase noise 836 MHz Reference spurs 836 MHz Phase noise 900 MHz Phase noise 900 MHz, over temperature and supply Reference spurs 900 MHz Reference spurs 900 MHz, over temperature and supply Phase noise 1750 MHz Reference spurs 1750 MHz Phase noise 1960 MHz Phase noise 1960 MHz, over temperature and supply Reference spurs 1960 MHz Reference spurs 1960 MHz, over temperature and supply Phase noise 2200 MHz Reference spurs 2200 MHz 6 TEST CONDITIONS PFD = 200 kHz, Loop Loop BW = 20 kHz, N =550, 550 Phase noise measured at 1-kHz 1 kHz offset spurs measured at ±PFD, ±2 x PFD MIN TYP MAX UNIT −106 dBc/Hz −110 dBc −99 dBc/Hz −110 dBc PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 2700, 2700 Phase noise measured at 1 1-kHz kHz offset spurs measured at ±PFD, ±2 x PFD −94 dBc/Hz −90 dBc PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 4180, 4180 Phase noise measured at 1 1-kHz kHz offset spurs measured at ±PFD, ±2 x PFD −91 dBc/Hz −100 dBc PFD = 200 kHz, Loop Loop BW = 20 kHz, N =1500, 1500 Phase noise measured at 1 1-kHz kHz offset spurs measured at ±PFD, ±2 x PFD PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 4500 4500, Phase noise measured at 1 1−kHz kHz offset spurs measured at ±PFD, ±2 x PFD −91 PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 4500, 4500 Phase noise measured at 1 1-kHz kHz offset spurs measured at ±PFD, ±2 x PFD −100 dBc −100 dBc PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 8750 Phase noise measured at 1-kHz offset spurs measured at ±PFD, ±2 x PFD −84 dBc/Hz −96 dBc PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 9800, 9800 Phase noise measured at 1 1-kHz kHz offset spurs measured at ±PFD, ±2 x PFD −84 PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 9800, 9800 Phase noise measured at 1-kHz 1 kHz offset spurs measured at ±PFD, ±2 x PFD −90 dBc −90 dBc PFD = 200 kHz, Loop Loop BW = 20 kHz, N = 11000 11000, Phase noise measured at 1 1-kHz kHz offset spurs measured at ±PFD, ±2 x PFD −83 dBc/Hz −90 dBc −90 −82 dBc/Hz dBc/Hz TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 PRODUCT TIMING CHARACTERISTICS AVDD = DVDD = 3.3 V ±10% or 5 V ±10% , TA = −40°C to 85°C (unless otherwise stated) PARAMETER TEST CONDITIONS MIN period(1) TYP MAX UNIT t(CLK) Clock 50 ns tsu1 Data setup time(2) 10 ns th Data hold time(2) 10 ns tw LE pulse width(2) 20 ns tsu2 LE setup time(2) 10 ns (1) Production tested. (2) Assured by design. t(CLK) CLOCK tsu1 th DATA DB20 (MSB) DB19 DB2 DB1 DB0 (LSB) tw LE tsu2 Figure 1. Serial Programming Timing Diagram 7 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 TYPICAL CHARACTERISTICS (Conditions are based on Electrical Characteristics table on page 6, unless otherwise noted) OUTPUT POWER vs FREQUENCY −10 Reference Level = −7.4 dBm PO − Output Power − dBc −20 −30 −40 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 100 Hz Video Bandwidth = 100 Hz Average = 30 PFD = 200 kHz Loop Loop BW = 20 kHz −50 −60 −70 −80 −90 −40 RMS = 0.14° PFD = 200 kHz Loop BW = 20 kHz −50 −60 Phase Noise − dBc/Hz 0 PHASE NOISE vs FREQUENCY −110 dBc −70 −80 −90 −100 −110 −120 −100 −130 −110 −120 −500−400 −300 −200 −100 0 −140 100 100 200 300 400 500 f − Frequency Offset from 110 MHz Carrier − kHz 1k Figure 2. Reference Spurs (RFOUT = 110 MHz) PO − Output Power − dBc −20 −30 −40 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 300 Hz Video Bandwidth = 300 Hz Average = 20 PFD = 200 kHz Loop BW = 20 kHz −50 −60 −70 −80 −90 −108 dBc −100 −40 RMS = 0.18° PFD = 200 kHz Loop BW = 20 kHz −50 −60 −70 −80 −90 −100 −110 −120 −130 −110 −120 −500−400 −300 −200 −100 0 100 200 300 400 500 f − Frequency Offset from 300 MHz Carrier − kHz Figure 4. Reference Spurs (RFOUT = 300 MHz) 8 1M PHASE NOISE vs FREQUENCY Phase Noise − dBc/Hz −10 Reference Level = −5.5 dBm 100k Figure 3. Integrated Phase Noise (RFOUT = 110 MHz) OUTPUT POWER vs FREQUENCY 0 10k f − Frequency Offset from 110 MHz Carrier − Hz −140 100 1k 10k 100k f − Frequency Offset from 300 MHz Carrier − Hz Figure 5. Integrated Phase Noise (RFOUT = 300 MHz) 1M TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 TYPICAL CHARACTERISTICS OUTPUT POWER vs FREQUENCY Reference Level = −5.7 dBm PO − Output Power − dBc −20 −30 −40 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 kHz Video Bandwidth = 1 kHz Average = 30 PFD = 200 kHz Loop BW = 20 kHz −50 −60 −70 −91.5 dBc −80 −90 −40 RMS = 0.36° PFD = 200 kHz Loop BW = 20 kHz −50 −60 Phase Noise − dBc/Hz 0 −10 PHASE NOISE vs FREQUENCY −70 −80 −90 −100 −110 −120 −100 −130 −110 −120 −500−400 −300 −200 −100 0 −140 100 100 200 300 400 500 1k Figure 6. Reference Spurs (RFOUT = 540 MHz) PO − Output Power − dBc −20 −30 −40 AVDD = AVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 kHz Video Bandwidth = 1 kHz Average = 30 PFD = 200 kHz Loop BW = 20 kHz −50 −60 −70 −80 1M PHASE NOISE vs FREQUENCY −100 dBc −90 −40 RMS = 0.39° PFD = 200 kHz Loop BW = 20 kHz −50 −60 Phase Noise − dBc/Hz −10 Reference Level = −5.7 dBm 100k Figure 7. Integrated Phase Noise (RFOUT = 540 MHz) OUTPUT POWER vs FREQUENCY 0 10k f − Frequency Offset from 540 MHz Carrier − Hz f − Frequency Offset from 540 MHz Carrier − kHz −70 −80 −90 −100 −110 −120 −100 −130 −110 −120 −500−400 −300 −200 −100 0 100 200 300 400 500 f − Frequency Offset from 836 MHz Carrier − kHz Figure 8. Reference Spurs (RFOUT = 836 MHz) −140 100 1k 10k 100k 1M f − Frequency Offset from 836 MHz Carrier − Hz Figure 9. Integrated Phase Noise (RFOUT = 836 MHz) 9 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 TYPICAL CHARACTERISTICS OUTPUT POWER vs FREQUENCY 0 −30 −40 Reference Level = −5.4 dBm −10 −20 PO − Output Power − dBc −20 PO − Output Power − dBc 0 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 kHz Video Bandwidth = 1 kHz Average = 30 PFD = 200 kHz Loop BW = 20 kHz Reference Level = −5.5 dBm −10 OUTPUT POWER vs FREQUENCY −50 −60 −70 −80 −100 dBc −90 −30 −40 −50 −60 −70 −90 −110 −120 −500−400 −300 −200 −100 0 −100 −2.5 −2.0 −1.5 −1.0 −0.5 0.0 0.5 1.0 1.5 2.0 2.5 100 200 300 400 500 f − Frequency Offset from 900 MHz Carrier − kHz f − Frequency Offset from 900 MHz Carrier − kHz Figure 10. Reference Spurs (RFOUT = 900 MHz) Figure 11. Phase Noise (RFOUT = 900 MHz) PHASE NOISE vs FREQUENCY −40 OUTPUT POWER vs FREQUENCY 0 RMS = 0.40° PFD = 200 kHz Loop BW = 20 kHz −50 −10 PO − Output Power − dBc Phase Noise − dBc/Hz Reference Level = −5.3 dBm −20 −60 −70 −80 −90 −100 −110 −120 −30 −40 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 kHz Video Bandwidth = 1 kHz Average = 25 PFD = 200 kHz Loop BW = 20 kHz −50 −60 −70 −96 dBc −80 −90 −100 −130 −110 −140 100 1k 10k 100k f − Frequency Offset from 900 MHz Carrier − Hz Figure 12. Integrated Phase Noise (RFOUT = 900 MHz) 10 −93 dBc/Hz −80 −100 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 Hz Video Bandwidth = 1 Hz Average = 30 PFD = 200 kHz Loop BW = 20 kHz 1M −120 −500−400 −300 −200−100 0 100 200 300 400 500 f − Frequency Offset from 1750 MHz Carrier − kHz Figure 13. Reference Spurs (RFOUT = 1750 MHz) TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 TYPICAL CHARACTERISTICS PHASE NOISE vs FREQUENCY −40 OUTPUT POWER vs FREQUENCY 0 RMS = 0.95° RMS = 0.95° PFD = 200 kHz Loop BW = 20 kHz −50 −20 −70 PO − Output Power − dBc Phase Noise − dBc/Hz −60 −80 −90 −100 −110 −120 −30 −40 −50 −60 −70 −92 dBc −80 −90 −100 −130 −110 −140 100 1k 10k 100k −120 −500−400 −300 −200−100 0 1M f − Frequency Offset from 1750 MHz Carrier − Hz PO − Output Power − dBc −20 −30 OUTPUT POWER vs FREQUENCY Reference Level = −6.7 dBm AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 Hz Video Bandwidth = 1 Hz Average = 30 PFD = 200 kHz Loop BW = 20 kHz −40 −50 −60 −70 Figure 15. Reference Spurs (RFOUT = 1960 MHz) −84 dBc/Hz −80 PHASE NOISE vs FREQUENCY −40 RMS = 0.98° PFD = 200 kHz Loop BW = 20 kHz −50 −60 Phase Noise − dBc/Hz −10 100 200 300 400 500 f − Frequency Offset from 1960 MHz Carrier − kHz Figure 14. Phase Noise (RFOUT = 1750 MHz) 0 AVDD = DVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 kHz Video Bandwidth = 1 kHz Average = 30 PFD = 200 kHz Loop BW = 20 kHz Reference Level = −6.9 dBm −10 −70 −80 −90 −100 −110 −120 −90 −130 −100 −2.5 −2.0 −1.5 −1.0 −0.5 0.0 0.5 1.0 1.5 2.0 2.5 f − Frequency Offset from 1960 MHz Carrier − kHz Figure 16. Phase Noise (RFOUT = 1960 MHz) −140 100 1k 10k 100k 1M f − Frequency Offset from 1960 MHz Carrier − Hz Figure 17. Integrated Phase Noise (RFOUT = 1960 MHz) 11 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 TYPICAL CHARACTERISTICS OUTPUT POWER vs FREQUENCY 0 −30 −40 −60 −50 −60 −70 RMS = 0.98° PFD = 200 kHz Loop BW = 20 kHz −50 Phase Noise − dBc/Hz −20 PO − Output Power − dBc −40 AVDD = AVDD = 3.3 V ICP = 5 mA Res. Bandwidth = 1 kHz Video Bandwidth = 1 kHz Average = 25 PFD = 200 kHz Loop BW = 20 kHz Reference Level = −7.0 dBm −10 PHASE NOISE vs FREQUENCY −90 dBc −80 −90 −70 −80 −90 −100 −110 −120 −100 −130 −110 −120 −500−400 −300 −200 −100 0 −140 100 100 200 300 400 500 1k Figure 18. Reference Spurs (RFOUT = 2200 MHz) −90 VCP = 7 V VCP = 7 V −95 1960 MHz, AVDD = DVDD = 3.3 V Reference Spur Level − dBc −80 Phase Noise − dBc/Hz 1M REFERENCE SPUR LEVEL vs FREE-AIR TEMPERATURE −75 −85 1960 MHz, AVDD = DVDD = 5 V 900 MHz, AVDD = DVDD = 5 V −90 900 MHz, AVDD = DVDD = 3.3 V −95 1960 MHz, AVDD = DVDD = 3.3 V 1960 MHz, AVDD = DVDD = 5 V −100 −105 900 MHz, AVDD = DVDD = 5 V −110 900 MHz, AVDD = DVDD = 3.3 V −115 −20 0 20 40 60 TA − Free-Air Temperature − °C Figure 20. 12 100k Figure 19. Integrated Phase Noise (RFOUT = 2200 MHz) PHASE NOISE vs FREE-AIR TEMPERATURE −100 −40 10k f − Frequency Offset from 2200 MHz Carrier − Hz f − Frequency Offset from 2200 MHz Carrier − kHz 80 100 −120 −40 −20 0 20 40 60 TA − Free-Air Temperature − °C Figure 21. 80 100 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 TYPICAL CHARACTERISTICS REFERENCE SPURS vs VTUNE CURRENT vs PRESCALER SETTING 0 12 IAVDD −10 −30 −40 I − Current − mA Reference Spurs − dBc IDVDD 10 −20 −50 −60 −70 VCP = 7 V −80 8 6 4 VCP = 5 V −90 2 −100 −110 1 2 3 VTUNE − V Figure 22. 4 0 0 8 16 24 32 40 48 56 64 Prescaler Setting Figure 23. 13 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Table 1. S11 Data for RFIN Buffer 14 FREQ (Hz) MAG(S11) PHASE(S11) 300M 849.388m 1.07722 344M 848.792m 1.02901 388M 848.317m 998.914m 432M 847.916m 981.324m 476M 847.565m 972.594m 520M 847.25m 970.294m 564M 846.962m 972.761m 608M 846.696m 978.834m 652M 846.448m 987.691m 696M 846.217m 998.737m 740M 846m 1.01154 784M 845.797m 1.02578 828M 845.605m 1.04122 872M 845.425m 1.05768 916M 845.255m 1.07502 960M 845.094m 1.09312 1.004G 844.943m 1.11191 1.048G 844.8m 1.13131 1.092G 844.664m 1.15127 1.136G 844.535m 1.17173 1.18G 844.413m 1.19267 1.224G 844.296m 1.21403 1.268G 844.185m 1.2358 1.312G 844.079m 1.25795 1.356G 843.978m 1.28045 1.4G 843.88m 1.30327 1.444G 843.787m 1.32641 1.488G 843.697m 1.34985 1.532G 843.61m 1.37355 1.576G 843.526m 1.39752 1.62G 843.444m 1.42174 1.664G 843.365m 1.44619 1.708G 843.288m 1.47086 1.752G 843.214m 1.49574 1.796G 843.14m 1.52082 1.84G 843.069m 1.54608 1.884G 842.999m 1.57152 1.928G 842.93m 1.59713 1.972G 842.862m 1.62291 2.016G 842.796m 1.64883 2.06G 842.73m 1.6749 2.104G 842.665m 1.70111 2.148G 842.601m 1.72744 2.192G 842.537m 1.7539 2.236G 842.474m 1.78048 2.28G 842.411m 1.80717 2.324G 842.349m 1.83397 2.368G 842.287m 1.86086 2.412G 842.225m 1.88786 2.456G 842.164m 1.91494 2.5G 842.103m 1.94211 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 FUNCTIONAL DESCRIPTION REFIN Stage This input typically comes from an external oscillator and is the reference used to synthesize the desired frequency on the output of the complete PLL. The equivalent schematic of this section is given in Figure 24. The output of this section goes to the R divider, so that the desired PFD frequency can be implemented. PDZ PDZ R PD PD Figure 24. REFIN Stage RFIN Stage Figure 25 shows the input stage of the TRF3750. This is where the output of the external VCO is fed back to the synthesizer. The RFIN signal subsequently feeds the prescaler section. AVDD RFIN VBIAS RFINB Figure 25. RFIN Stage Prescaler Stage This stage divides down the RFIN frequency before the A and B counters. This is a dual-modulus prescaler and the user can select any of the following settings: 8/9, 16/17, 32/33, and 64/65. A and B Counter Stage The TRF3750 includes a 6-bit A counter and a 13-bit B counter that operate on the output of the prescaler. The A counter can take values from 0 to 63, while the B counter can take values from 3 to 8191. Also, the value for the B counter has to be greater than or equal to the value for the A counter. These are CMOS devices, and can easily operate up to 200 MHz. The selection of the prescaler needs to be such that the resultant frequency does not exceed the rated 200-MHz threshold. R Divider The output of the REFIN stage is fed into the R divider stage. The 14-bit R divider allows the input reference frequency to be divided down to produce the reference clock to the phase frequency detector (PFD). Division ratios from 1 to 16,383 are allowed. 15 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Phase Frequency Detector (PFD) and Charge Pump Stage The outputs of the R divider and the N counter (please see pulse swallow section) are fed into the PFD stage, where the two signals are compared in frequency and phase. The TRF3750 features an anti-backlash pulse, whose width is controllable by the user, in order to optimize phase and spurious performance. The PFD feeds the charge pump, which is the final output of the TRF3750. The charge pump output pulses need to be fed into an external loop filter, which eventually produces the tuning voltage needed to control the external VCO to the desired frequency. Pulse Swallow/Frequency Synthesis The different stages of the TRF3750 enable the user to synthesize a large range of frequencies at the output of a complete PLL. For a given reference frequency (fREFIN), the user’s choice of the R divider yields the PFD frequency (fPFD), which is the step by which the resultant output frequency can be incremented or decremented. The choice of prescaler, and A and B counters yields the output frequency at the external VCO (RFOUT) as shown below. RFOUT = fPFD x N = (fREFIN / R) x (A + P x B) MUXOUT Stage The TRF3750 features a multiplexer that allows programmable access to several signals. Table 5 and Table 6 show the truth tables. Some of the different signals available are detailed below. Digital Lock Detect This is an active high digital output that indicates when the device has achieved lock. The user can choose between two precision settings for the lock detection, through the reference counter latch. A 0 on the lock detect precision means that the digital lock detect output goes high only if three contiguous cycles of the PFD have an error of less than 15 ns. A 1 would require five contiguous cycles (a more stringent condition). Any error of greater than 25 ns, even on one cycle, would produce a 0 in the digital lock detect signal, indicating loss of lock. Analog Lock Detect Selecting the analog lock detect option at the output of the output multiplexer requires an external pull-up resistor (≈10 kΩ) to be placed on the output (MUXOUT, pin 14). Fastlock Mode The TRF3750 features two Fastlock Modes, which the user may select depending on the particular application. There are two separate charge pump current settings (1 and 2) that can be programmed, and the Fastlock Modes, when activated, enable the device to quickly switch from current setting 1 to current setting 2. The two Fastlock Modes (1 and 2) differ in the way the device reverts back to current setting 1. In normal (steady-state) operation, current setting 1 is used. For transient situations such as frequency jumps, current setting 2 can be used. Fastlock Mode 1 As soon as Fastlock Mode 1 is entered, the charge pump current is switched to the preprogrammed setting 2 and stays there until the charge pump gain programming bit is set to 0 in the N counter latch. This way, the user has immediate software control of the transition between charge pump setting 1 and 2. Fastlock Mode 2 As soon as Fastlock Mode 2 is entered, the charge pump current is switched to the preprogrammed setting 2 and stays there until the timer counter has expired. The timer counter is programmed by the user and counts how many PFD cycles the device spends in current setting 2 in Fastlock Mode 2. The number of timer cycles can be set in increments of four cycles in the range of 3 to 63. When the counter has expired, the device returns to normal operation (fastlock disabled and charge pump current setting 1). This way no extra programming is needed in order for the device to exit fastlock. 3-Wire Serial Programming The TRF3750 features an industry-standard 3-wire serial interface that controls an internal 24-bit shift register. There are a total of 3 signals that need to be applied: the clock (CLK, pin 11), the serial data (DATA, pin 12) and the load enable (LE, pin13). The DATA (DB0−DB23) is loaded MSB first and is read on the rising edge of the CLK. The LE signal is asynchronous to the clock and at its rising edge the DATA gets loaded onto the 16 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 selected latch. The last two bits of the serial data (DB0 and DB1) are the bits that control one of the four available latches (R counter latch, N counter latch, function latch, and initialization latch). The truth table for selecting the appropriate latch is shown in Table 2. Table 2. Latch Selection Truth Table DB1 (C2) DB0 (C1) SELECTED DATA LATCH 0 0 R counter 0 1 N counter 1 0 Function 1 1 Initialization 17 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Latch Description Table 3. R Counter Latch Reserved Lock Detect Precision DB23 DB22 DB21 DB20 X† DLY SYNC LDP Test Mode Bits Anti Backlash Pulse Width DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 DB10 T2 T1 ABP2 ABP1 Control Bits 14-Bit Reference Counter, R R14 R13 R12 R11 R10 R9 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 R8 R7 R6 R5 R4 R3 R2 R1 C2(0) C1(0) Set to 00 AntiBacklash Pulse Width 0 0 3 ns 0 1 1.5 ns 1 0 6 ns 1 1 3 ns LDP Operation 0 3 contiguous cycles of phase delay < 15 ns must occur before Lock Detect is set. 1 5 contiguous cycles of phase delay < 15 ns must occur before Lock Detect is set. SYNC 0 0 Normal operation 0 1 Prescaler resynchronized with nondelayed form of RF input 1 0 Normal operation 1 Prescaler resynchronized with delayed form of RF input X = Don’t Care 18 ABP1 DLY 1 † ABP2 Operation R14 R13 R12 ••• R3 R2 R1 Divide Ratio 0 0 0 ••• 0 0 1 1 0 0 0 ••• 0 1 0 2 0 0 0 ••• 0 1 1 3 0 0 0 ••• 1 0 0 4 • • • ••• • • • • • • • ••• • • • • • • • ••• • • • • 1 1 1 ••• 1 0 0 16380 1 1 1 ••• 1 0 1 16381 1 1 1 ••• 1 1 0 16382 1 1 1 ••• 1 1 1 16383 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Latch Description (Continued) Table 4. AB Counter Latch Reserved CP Gain DB23 DB22 DB21 X† X† G1 13-Bit B Counter DB20 DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 DB10 B13 B12 B11 B10 B9 B8 Control Bits 6-Bit A Counter B7 B6 B5 B4 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 B2 B1 A6 A5 A4 A3 A2 A1 C2(0) C1(1) B3 B≥A B12 B11 ••• B3 B2 B1 B Counter Divide Ratio A6 A5 ••• A2 A1 A Counter 0 0 0 ••• 0 0 0 N/A 0 0 ••• 0 0 0 0 0 0 ••• 0 0 1 N/A 0 0 ••• 0 1 1 0 0 0 ••• 0 1 0 N/A 0 0 ••• 1 0 2 0 0 0 ••• 0 1 1 3 0 0 ••• 1 1 3 0 0 0 ••• 1 0 0 4 • • ••• • • • • • • ••• • • • • • • ••• • • • • • • ••• • • • • • • ••• • • • • • • ••• • • • • 1 1 ••• 0 0 60 1 1 1 ••• 0 0 0 8188 1 1 ••• 0 1 61 1 1 1 ••• 0 0 1 8189 1 1 ••• 1 0 62 1 1 1 ••• 1 1 0 8190 1 1 ••• 1 1 63 1 1 1 ••• 1 1 1 8191 F4 (Function Latch D89) Fastlock Enable CP Gain Charge Pump Current Setting Operation 0 0 Current setting 1 is always used 0 1 Current setting 2 is always used 1 0 1 † B13 1 Current setting 1 used Current setting 2 is used until fastlock mode exits (returns to current setting 1) X = Don’t Care 19 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Latch Description (Continued) Table 5. Function Latch Prescaler Value Power Down 2 DB23 DB22 DB21 DB20 DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 PD2 CP16 CP15 CP14 CP13 CP12 CP11 TC4 P2 P1 Current Setting 2 Current Setting 1 CP16 CP15 CP14 CP13 CP12 CP11 † Reserved DB10 DB9 DB8 DB7 F5 F4 F3 X{ MUXOUT Control Power Down 1 Counter Reset Control Bits DB6 DB5 DB4 DB3 DB2 DB1 DB0 PD1 F1 C2(1) C1(0) M3 M2 F1 4.7 kΩ 10 kΩ Normal 1 R, A, B counters reset M2 M1 Output 0 0 0 3-State output 0 0 1 Digital lock detect 0 1 0 N divider output 0 1 1 DVDD 1 0 0 R divider output 1 0 1 Analog lock detect 0.29 0 0 1 2.18 1.25 0.59 0 1 0 3.26 1.88 0.88 F3 Charge Pump Output 0 1 1 4.35 2.50 1.76 0 Normal M3 1 0 0 5.44 3.13 1.47 1 Tri-State 1 0 1 6.53 3.75 1.76 1 1 0 7.62 4.38 2.06 1 1 1 8.70 5.00 2.35 8/9 0 1 16/17 1 0 32/33 1 1 64/65 F4 F5 Fastlock Mode 0 X† Fastlock disable 1 0 Fastlock mode 1 1 1 Fastlock mode 2 Counter Operation 0 0.63 0 M1 ICPOUTmax (mA) 2.7 kΩ 1.09 0 20 CP Tri-State 0 Prescaler Value TC4 TC3 TC2 TC1 Timeout (PFD Cycles) 1 1 0 Serial data output 0 0 0 0 3 1 1 1 DGND 0 0 0 1 7 0 0 1 0 11 0 0 1 1 15 0 1 0 0 19 0 1 0 1 23 Mode 0 1 1 0 27 0 1 1 1 31 1 0 0 0 35 1 0 0 1 39 1 0 1 0 43 1 0 1 1 47 1 1 0 0 51 1 1 0 0 55 1 1 1 0 59 1 1 1 1 63 0 X† X† Asynchronous power down 1 X† 0 Normal operation 1 0 1 Asynchronous power down 1 1 1 Synchronous power down X = Don’t Care TC1 Fastlock Enable 0 P1 PD2 PD1 TC3 TC2 Fastlock Mode 0 P2 CE (Pin 10) Timer Counter Control TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Latch Description (Continued) Table 6. Initialization Latch Prescaler Value Power Down 2 DB23 DB22 DB21 DB20 DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 PD2 CP16 CP15 CP14 CP13 CP12 CP11 TC4 P2 P1 Current Setting 2 Current Setting 1 † TC1 Fastlock Enable CP 3-State DB10 DB9 DB8 DB7 F5 F4 F3 X{ Reserved MUXOUT Control Power Down 1 Counter Reset Control Bits DB6 DB5 DB4 DB3 DB2 DB1 DB0 PD1 F1 C2(1) C1(1) M3 M2 M1 2.7 kΩ 4.7 kΩ 10 kΩ F1 Counter Operation 0 Normal 1 R, A, B counters reset 0 0 0 1.09 0.63 0.29 0 0 1 2.18 1.25 0.59 0 1 0 3.26 1.88 0.88 F3 Charge Pump Output 0 1 1 4.35 2.50 1.76 0 Normal M3 M2 M1 Output 1 0 0 5.44 3.13 1.47 1 3-State 0 0 0 3-State output 1 0 1 6.53 3.75 1.76 0 0 1 Digital lock detect 1 1 0 7.62 4.38 2.06 0 1 0 N divider output 1 1 1 8.70 5.00 2.35 0 1 1 DVDD 1 0 0 R divider output P2 P1 Prescaler Value 0 0 8/9 0 1 16/17 1 0 32/33 1 1 64/65 CE (Pin 10) TC3 TC2 Fastlock Mode ICPOUTm,ax (mA) CP16 CP15 CP14 CP13 CP12 CP11 Timer Counter Control F4 F5 Fastlock Mode 0 X Fastlock disable 1 0 Fastlock mode 1 1 1 Fastlock mode 2 TC4 TC3 TC2 TC1 Timeout (PFD Cycles) 0 0 0 0 3 0 0 0 1 7 0 0 1 0 11 0 0 1 1 15 0 1 0 0 19 0 1 0 1 23 PD2 PD1 Mode 0 1 1 0 27 0 X X Asynchronous power down 0 1 1 1 31 1 X 0 Normal operation 1 0 0 0 35 1 0 1 Asynchronous power down 1 0 0 1 39 1 1 1 Synchronous power down 1 0 1 0 43 1 0 1 1 47 1 1 0 0 51 1 1 0 0 55 1 1 1 0 59 1 1 1 1 63 1 0 1 Analog lock detect 1 1 0 Serial data output 1 1 1 DGND X = Don’t Care 21 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 R Counter Latch By selecting (0,0) for the control bits DB0 and DB1, the R counter latch is selected. Table 7 shows the setup of the R counter latch. Reserved Table 7. R Counter Latch DLY SYNC DB23 DB22 DB21 X DLY SYNC Lock Detect Precision DB20 LDP Test Mode Bits Anti Backlash Width Control Bits 14-Bit Reference Counter; R DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 DB10 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 T2 T1 ABP2 ABP1 R14 R13 R12 R11 R10 R9 R8 R7 R6 R5 R4 R3 R2 DB0 R1 C2(0) C1(0) R Value This latch is used primarily to select the R divider for the input reference signal (REFIN). DB2 through DB15 are used to select the chosen value for the 14-bit counter. DB2 is the LSB and DB15 the MSB. Anti-backlash Pulse DB16 and DB17 can be used to select the width of the anti-backlash pulse in the PFD. In any PFD implementation, there is an inherent risk of backlash, a phenomenon that can occur when the device is almost in lock. In order to ensure that there are always pulses coming out of the charge pump and that therefore the VCO cannot drift out of lock, the TRF3750 employs an anti-backlash pulse. The user can select the width of the anti-backlash pulse; the values allowed are 1.5 ns, 3 ns, and 6 ns. Lock Detect Precision Setting DB20 of the R counter latch to 0 results in a precision of three cycles for the lock detect, while setting it to 1 results in a precision of five cycles. Sync / Delay DB21−22 control the sync/delay operation of the device. If DB21 is 0, then the device is in normal operation. Assuming DB21 is set to 1, setting DB22 to 0 utilizes a non-delayed form of the RF signal for the resynchronization of the prescaler output, whereas setting DB22 to 1 utilizes a delayed form. Reserved Bits Bits DB18, DB19 and DB23 of the R counter latch are reserved. It is recommended to keep those bits 0 for normal operation. N Counter Latch Setting (DB1, DB0) = (0,1) for the latch control bits selects the N counter latch. Table 8 shows the setup of the N counter latch. Table 8. N Counter Latch CP Reserved Gain 13-Bit B Counter 6-Bit B Counter Control Bits l DB23 DB22 DB21 DB20 DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 DB10 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 X X G1 B13 B12 B11 D10 B9 B8 B7 B6 B5 B4 B3 B2 B1 A6 A5 A4 A3 A2 A1 C2(0) C1(0) A Counter The 6 bits DB2−DB7 control the value of the A counter. The valid range is from 0 to 63. For example, programming (DB7, DB6, DB5, DB4, DB3,DB2) = (0,0,0,0,1,0) results in a value of 2 for the A counter. B Counter The 13 bits DB8−DB20 of the N counter latch control the value of the B counter. The valid range is from 3 to 8191. For example, (DB20, DB19, …, DB10, DB9, DB8) = (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0) results in a value of 4 for the B counter. Charge Pump Gain DB21 of the N counter latch determines when the TRF3750 enters Fastlock Mode. When this bit is 1, the device switches into fastlock and when this bit is 0, the device exits fastlock (fastlock mode 1). 22 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Reserved Bits Bits DB22−DB23 of the N counter latch are reserved and can be treated as don’t cares by the user. Function Latch Table 9 depicts the function latch. By selecting (0,1) for the control bits DB0 and DB1, the function latch is selected. Table 9. Function Latch Power CP Prescaler Power MUXOUT Current Counter Control Timer Counter Fasklock Fasklock Current Down Down Tri− Reserved Value Control Bits Setting 2 Reset Control Mode Enable Setting 1 2 1 State DB23 DB22 DB21 DB20 DB19 DB18 DB17 DB16 DB15 DB14 DB13 DB12 DB11 DB10 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 P2 P1 PD2 CPI6 CPI5 CPI4 CPI3 CPI2 CPI1 TC4 TC3 TC2 TC1 F5 F4 F3 M3 M2 M1 PD1 F1 C2(1) C1(0) X Counter Reset Bit When this bit is set to 1, all the counters in the PLL are reset. This includes the R, A, and B counters. In a typical application, this bit should be set to 0. Power Down The complete power down functionality of the TRF3750 is controlled in software by the two bits DB3 and DB21 in the function latch and in hardware by the external pin CE (pin 10). When the TRF3750 enters the power down state, the power consumption is lowered, the charge pump is 3-stated, but the registers are still operational enabling programming of the device. The hardware power down (CE set to 0) is immediate and asynchronous. Assuming that CE is set to 1, the two bits can select between the software power down options available. Setting DB3 to 0 enables normal operation of the PLL. When (DB21, DB3) = (0,1), then the asynchronous power down is selected, which means that the device powers down as soon as the programming is read. When (DB21, DB3) = (1,1), then the synchronous power down is enabled. In this mode, the device enters power down on the next cycle of the charge pump. This is a more controlled power down, as it avoids potential transients or erroneous output frequencies. MUXOUT Bits DB4, DB5, and DB6 determine what signal appears at the output of the internal multiplexer, as described in Table 5. For example, the most widely used output signal on this pin would be the digital lock detect signal, which goes high when lock has been achieved. In order to program this mode, the user has to set (DB4, DB5, DB6) = (1,0,0). Charge Pump 3-state DB8 of the function latch can set the output of the charge pump in a 3-state mode, if set to 1. Normal operation of the device is attained when this bit is 0. Fastlock Enable and Mode Setting DB9 of the function latch to 1 enables the Fastlock Mode, whereas setting it to 0 deactivates this feature altogether. Assuming that DB9 is 1, DB10 selects between the two possible Fastlock Modes: Fastlock Mode 1 is selected when DB10 is 0, whereas Fastlock Mode 2 is selected when DB10 is 1. The device actually enters fastlock when the charge pump gain bit in the N counter latch (DB21) is set to 1. Once in Fastlock Mode 1, the device switches back when DB21 of the N counter latch is set to 0. Conversely, once in Fastlock Mode 2, the device switches back after the timeout condition has been reached, at which point DB21 of the N counter latch is automatically set to 0. Timer Counter Control DB11−DB14 of the function latch control the timer counter, in case the Fastlock Mode 2 was selected. These four bits give the user the capability to program the number of PFD cycles that elapse before the device exits the Fastlock Mode. Valid values for this are 3 to 63, in steps of 4 cycles. For example, programming (DB14, DB13, DB12, DB11) = (0,0,1,0) results in 11 cycles before the Fastlock Mode times out. Current Settings 1 and 2 DB15−DB17 control the maximum charge pump current setting 1, while DB18−20 control current setting 2. The actual value of the maximum charge pump current will be dictated by the resistor placed outside on RSET (pin1). 23 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Prescaler Selection DB22−DB23 of the function latch controls the prescaler value for the device. There are four possible settings (9/9, 16/17, 32/33, 64/65). For example, setting (DB23, DB22) = (1,0) results in a prescaler choice of 32/33. Initialization Latch / Programming After Power Up Setting (DB1, DB0) = (1,1) selects the initialization latch. The make-up and programming of the initialization latch is identical to that of the function latch. The difference here is that this latch can be used in order to program the device at power up. When the initialization latch is programmed, an internal reset occurs at all the counters (R, A, B) who become ready to get loaded, assuring that the next time data is loaded for the A and B counters the device begins counting efficiently. Subsequent programming of the A and B counters will not, however, cause this internal pulse to recur. This pulse is also used to gate the synchronous power down when that mode is engaged. As soon as the device exits power down, the counting resumes promptly. Alternate Ways of Programming After Power Up In addition to the method of using the initialization latch described above, the user can also utilize the CE pin to achieve initialization. Since the CE does not halt the operation of the serial port, the user can preprogram the counters and as soon as the device is enabled, the counters operate and the device reaches a steady-state and functions normally. A third option in power up is the counter reset method. The function latch is programmed with the desired data, and in addition DB2 (the counter reset bit) is set to 1. The R counter latch is programmed next, followed by the N counter latch. Finally, the function latch is programmed again, but this time with a 0 in the bit DB2, disabling the counter reset. The charge pump is 3-stated during the reset, but the synchronous power down is not triggered. Prescaler Resynchronization DB22 and DB21 of the R counter latch are used to control the delay (DLY) and resynchronization (SYNC) functions of the device. If SYNC is set to 1, then the output of the prescaler is resynchronized with the RF input. In addition, if DLY is also 1, the output of the prescaler gets resynchronized with a delayed form of the RF input signal. In either case, taking the SYNC to 0 reverts the device to normal operation. The use of the SYNC and DLY functionality can improve the device’s phase noise performance by a few dBs. It is, however, susceptible to potential malfunction, in case the chosen edge of the RF input coincides with the prescaler. This phenomenon may be mitigated by using the DLY function, but is nonetheless unpredictable and care should be applied, as fluctuations in temperature, supply and frequency can alter the point at which the feature fails to operate. The normal operation of the device calls for both DLY and SYNC to be set to 0, which is the way the TRF3750 has been characterized. 24 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 APPLICATION INFORMATION SYNTHESIZING A SELECTED FREQUENCY The TRF3750 is an integer-N PLL synthesizer, and because of its flexibility (14-bit R, 6-bit A, 13-bit B counter, and dual modulus prescaler), is ideal for synthesizing virtually any desired frequency. Let us assume that we need to synthesize a 900-MHz local oscillator, with spacing capability (minimum frequency increment) of 200 kHz, as in a typical GSM application. The choice of the external reference oscillator to be used is beyond the scope of this section, but assuming that a 10-MHz reference is selected, we calculate the settings that yield the desired output frequency and channel spacing. There is usually more than one solution to a specific set of conditions, so below is one way of achieving the desired result. First, select the appropriate R counter value. Since a channel spacing of 200 kHz is desired, the PFD can also be set to 200 kHz. Calculate the R value through R = REFIN/PFD = 10 MHz / 200 kHz = 50. Assume a prescaler value of 8/9 is selected. This is a valid choice, since the prescaler output will be well within the 200-MHz limit (900 MHz / 8 = 112.5 MHz). Select the appropriate A and B counter values. We know that RFOUT = fPFD x N = (fREFIN / R) x (A + P x B). Therefore, we need to solve the following equation: 900 MHz = 200 kHz x (A + 8 x B) Clearly there are many solutions to this single equation with two unknowns; there are some basic constraints on the solution, since 3 ≤ B ≤ 8191, and also B ≥ A. So, if we pick A = 4, solving the equation yields B = 562. Thus, one complete solution would be to choose: R = 50, A = 4, B = 562, and P = 8/9, resulting in the desired N = 4500. The GUI software accompanying the evaluation board of the TRF3750 includes an easy Parameter Selection Assistant that can directly propose appropriate values for all the counters given the user’s requirements. In addition, the software can configure all the possible settings of the TRF3750 and can output the data stream required, so that the user has a reference when programming the serial port. To complete the example, the serial port has to be programmed in order for the correct frequency to appear at the output of the complete PLL. Assuming that the user wanted to program the same modes as used in the RF Performance Specifications section, a possible sequence of serial data going into the device could be the one listed below for the three different latches (note that the initialization latch is not used in this example): Table 10. R Counter Latch Programming Example DB 23 DB 22 DB 21 DB 20 DB 19 DB 18 DB 17 DB 16 DB 15 DB 14 DB 13 DB 12 DB 11 DB 10 0 0 0 1 0 0 0 1 0 0 0 0 0 0 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 0 0 1 1 0 0 1 0 0 0 Table 11. N Counter Latch Programming Example DB 23 DB 22 DB 21 DB 20 DB 19 DB 18 DB 17 DB 16 DB 15 DB 14 DB 13 DB 12 DB 11 DB 10 0 0 0 0 0 0 1 0 0 0 1 1 0 0 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 1 0 0 0 0 1 0 0 0 1 Table 12. Function Latch Programming Example DB 23 DB 22 DB 21 DB 20 DB 19 DB 18 DB 17 DB 16 DB 15 DB 14 DB 13 DB 12 DB 11 DB 10 0 0 0 1 1 1 1 1 1 0 0 0 1 0 DB9 DB8 DB7 DB6 DB5 DB4 DB3 DB2 DB1 DB0 0 0 1 0 0 1 0 0 1 0 25 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Building a Complete PLL Using the TRF3750 This application of the TRF3750 is just one of many possible ways in which a wireless infrastructure transmitter LO can be implemented for GSM applications and beyond. Supplies/Decoupling Appropriate decoupling is important in ensuring optimum noise performance of the device. Ideally, the AVDD and DVDD supplies should be separated through a ferrite and be at the same potential. A larger capacitor, in the order of a 10 µF, should be placed in the supply chain, followed by a couple of small value decoupling capacitors very close to the device’s supply pins. Typical values are 0.1 µF and 10 pF. The decoupling capacitors should not be shared and should be chosen to have low ESR. The VCP supply needs to be at least 1 V greater than the AVDD and DVDD supplies and similar decoupling should be applied. Reference A large range of frequencies can be used for the reference input. In this example, an external TCXO of 10 MHz is used to provide the stable reference frequency for the REFIN pin of the device. The quality of the reference oscillator is important, and its phase noise needs to be significantly lower than what is expected of the entire loop as it does not get attenuated in the loop. Typically, such devices do not require 50-Ω terminations and can be taken into the PLL ac coupled. The TRF3750 has a large range of power levels that it can accept at the REFIN input; however stronger signals result typically in better phase noise performance. Values of +5 dBms (referred to 50 Ω) should yield excellent performance. The TRF3750 is compatible with most commercially available oscillators. VCO Selection Plenty of VCOs exist in the market that can cover the frequency range of all wireless applications today. One clear advantage of the TRF3750 is that it features an extended charge pump supply, allowing interface to VCOs with larger tuning ranges. VCP can be as high as 8 V, which implies that VCOs with tuning voltage ranges of 7 V can easily be accommodated. In closing the loop with the VCO, it is important to ensure that proper termination is observed, especially in the higher range of frequency operation. A standard resistive splitter implementation works well, where each of the three Rs in the classic T connection assume the value of 16.6 Ω. In other cases where impedance matching is less critical than getting maximum power out of the whole PLL loop, the user may decide to leave the resistors out and just tap off a trace from the VCO output and feed it back to the synthesizer. Additionally, a small series resistor can be placed in the feedback path towards the TRF3750 so as to reduce the relative power delivered to the PLL versus that available for the transmitter. The VCO’s supply should also be decoupled as recommended by the manufacturer. Loop Filter Design Numerous methodologies and design techniques exist for designing optimized loop filters for particular applications. The loop filter design can affect the stability of the loop, the lock time, the bandwidth, the extra attenuation on the reference spurs, etc. The role of the loop filter is to integrate and lowpass the pulses of the charge pump and eventually yield an output tuning voltage that drives the VCO. Several filter topologies can be implemented, including both passive and active. In this section, we use a third-order passive filter. For this example, we assume several design parameters. First, the VCO’s manufacturer should specify the device’s KV, which is given in MHz/V. Here we assume a value of 12 MHz/V, meaning that in the linear region, changing the tuning voltage of the VCO by 1 V induces a change of the output frequency of about 12 MHz. We already know that N = 4500 and that our fPFD = 200 kHz. We also further assume that current setting 1 will be used and be set to maximum current of 5 mA. In addition, we need to determine the bandwidth of the loop filter. This is a critical consideration as it affects (among other things) the lock time of the system. Assuming an approximate bandwidth of around 20 kHz is needed, and that for stability we desire a phase margin of about 45 degrees, the following values for the components of the loop filter can be derived. These values, along with the rest of the example circuitry, are shown in Figure 26. It is important to note here that there are almost infinite solutions to the problem of designing the loop filter and the designer is called to make tradeoff decisions for each application. 26 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Layout/PCB Considerations This section of the design of the complete PLL is of paramount importance in achieving the desired performance. Wherever possible, a multi-layer PCB board should be used, with at least one dedicated ground plane. A dedicated power plane (split between the supplies if necessary) is also recommended. The impedance of all RF traces (the VCO output and feedback into the PLL) should be controlled to 50 Ω. All small value decoupling capacitors should be placed as close to the device pins as possible. It is also recommended that both top and bottom layers of the circuit board be flooded with ground, with plenty of ground vias dispersed as appropriate. The most sensitive part of any PLL is the section between the charge pump output and the input to the VCO. This of course includes the loop filter components, and the corresponding traces. The charge pump is a precision element of the PLL and any extra leakage on its path can adversely affect performance. Extra care should be given to ensure that parasitics are minimized in the charge pump output, and that the trace runs are short and optimized. Similarly, it is also recommend that extra care is taken in ensuring that any flux residue is thoroughly cleaned and moisture baked out of the PCB. From an EMI perspective, and since the synthesizer is typically a small portion of a bigger, complex circuit board, shielding is recommended to minimize EMI effects. DVDD 10 pF + VCP AVDD VVCO 0.1 mF + 10 pF CE VCP REFIN CPOUT + 10 mF 20 kW 2 1 nF 10 nF V TUNE 82 pF GND RSET 1 RFINA 6 100 pF 16.5 W TRF3750 3.9 kW RSET OUT VCO 16.5 W 100 pF GND 16.5 W 4.7 kW 11 DATA 12 LE 13 CLK DATA LE MUXOUT 14 LOCK DETECT DGND CLK AGND DECOUPLING NOT SHOWN 8 CPGND GND 10 pF 16 1 nF TCXO (10-MHz Reference) 10 mF 15 7 10 AVDD SUPPLY LO Output to 50-W Load + 0.1 mF 0.1 mF 10 mF 0.1 mF 10 pF DVDD 10 mF 5 3 4 9 RFINB 100 pF 49.9 W 100 pF Figure 26. Example Application of the TRF3750 for GSM Wireless Infrastructure Transceivers Application Example for Direct IQ Upconversion Wireless Infrastructure Transmitter Much in the same way as described above, the TRF3750 is an ideal synthesizer to use in implementing a complete direct upconversion transmitter. Using a complete suite of high performance Texas Instruments components, a state-of-the-art transmitter can be implemented featuring excellent performance. Texas Instruments offers ideal solutions for the DSP portion of transceivers, for the digital upconverters, serializers/deserializers, and for the analog, mixed-signal, and RF components needed to complete the transmitter. The baseband digital data is converted to I and Q signals through the dual DAC5686, which features offset and gain adjustments in order to optimize the carrier and sideband suppressions of the direct IQ modulator. If additional gain is desired at the output of the DAC or if the user’s existing solution does not offer differential signals, the THS4503 differential amplifier can be used between the DAC and the modulator. The LO input of the IQ modulator is generated by the TRF3750 synthesizer in combination with an external VCO centered at the frequency of interest. The same considerations as the ones listed in the previous example still apply. In addition, the CDC7005 clocking solution can be used to clock the DAC and other portions of the transmitter. A block diagram of the proposed architecture is shown in Figure 27. For more details, contact Texas Instruments directly. 27 TRF3750 www.ti.com SLWS146A − MARCH 2004 − REVISED NOVEMBER 2004 Application Example for Direct IQ Upconversion Wireless Infrastructure Transmitter (Continued) Main Diversity DAC2904 or DAC5686 TRF370x PA Main GC5016 DAC I/Q DUC I/Q SERDES DUC I/Q SERDES DAC PA Diversity DAC I/Q Antenna Interface Unit TRF3750 PLL THS4503 VCO CDC7005 Baseband Channel Processor Figure 27. Texas Instruments’ Proposed Direct Upconversion Wireless Infrastructure Transmitter Architecture 28 Network DAC MECHANICAL DATA MTSS001C – JANUARY 1995 – REVISED FEBRUARY 1999 PW (R-PDSO-G**) PLASTIC SMALL-OUTLINE PACKAGE 14 PINS SHOWN 0,30 0,19 0,65 14 0,10 M 8 0,15 NOM 4,50 4,30 6,60 6,20 Gage Plane 0,25 1 7 0°– 8° A 0,75 0,50 Seating Plane 0,15 0,05 1,20 MAX PINS ** 0,10 8 14 16 20 24 28 A MAX 3,10 5,10 5,10 6,60 7,90 9,80 A MIN 2,90 4,90 4,90 6,40 7,70 9,60 DIM 4040064/F 01/97 NOTES: A. B. C. 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