DC-to-2.5 GHz High IP3 Active Mixer AD8343 High-performance active mixer Broadband operation to 2.5 GHz Conversion gain: 7 dB Input IP3: 16.5 dBm LO drive: –10 dBm Noise figure: 14 dB Input P1dB: 2.8 dBm Differential LO, IF and RF Ports 50 Ω LO input impedance Single-supply operation: 5 V @ 50 mA typical Power-down mode @ 20 μA typical FUNCTIONAL BLOCK DIAGRAM COMM 1 AD8343 14 COMM INPP 2 13 OUTP INPM 3 12 OUTM DCPL 4 11 COMM VPOS 5 10 LOIP BIAS PWDN 6 9 LOIM COMM 7 8 COMM 01034-001 FEATURES Figure 1. APPLICATIONS Cellular base stations Wireless LAN Satellite converters SONET/SDH radio Radio links RF instrumentation GENERAL DESCRIPTION The AD8343 is a high-performance broadband active mixer. With wide bandwidth on all ports and very low intermodulation distortion, the AD8343 is well suited for demanding transmit applications or receive channel applications. The AD8343 provides a typical conversion gain of 7 dB. The integrated LO driver supports a 50 Ω differential input impedance with low LO drive level, helping to minimize external component count. The open-emitter differential inputs can be interfaced directly to a differential filter or driven through a balun (transformer) to provide a balanced drive from a single-ended source. The LO driver circuitry typically consumes 15 mA of current. Two external resistors are used to set the mixer core current for required performance, resulting in a total current of 20 mA to 60 mA. This corresponds to power consumption of 100 mW to 300 mW with a single 5 V supply. The AD8343 is fabricated on Analog Devices, Inc.’s highperformance 25 GHz silicon bipolar IC process. The AD8343 is available in a 14-lead TSSOP package. It operates over a −40°C to +85°C temperature range. A device-populated evaluation board is available. The open-collector differential outputs can be used to drive a differential IF signal interface or convert to a single-ended signal through the use of a matching network or transformer. When centered on the VPOS supply voltage, the outputs swing ±1 V. Rev. B Information furnished by Analog Devices is believed to be accurate and reliable. However, no responsibility is assumed by Analog Devices for its use, nor for any infringements of patents or other rights of third parties that may result from its use. Specifications subject to change without notice. No license is granted by implication or otherwise under any patent or patent rights of Analog Devices. Trademarks and registered trademarks are the property of their respective owners. One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A. Tel: 781.329.4700 www.analog.com Fax: 781.461.3113 ©2006 Analog Devices, Inc. All rights reserved. AD8343 TABLE OF CONTENTS Features .............................................................................................. 1 Power-Down Interface (PWDN) ............................................. 16 Applications....................................................................................... 1 AC Interfaces................................................................................... 17 Functional Block Diagram .............................................................. 1 Input Interface (INPP and INPM) ............................................... 18 General Description ......................................................................... 1 Single-Ended-to-Differential Conversion............................... 18 Revision History ............................................................................... 2 Input Matching Considerations ............................................... 18 Specifications..................................................................................... 3 Input Biasing Considerations ................................................... 19 Basic Operating Instructions ...................................................... 3 Output Interface (OUTP, OUTM) ............................................... 20 Typical AC Performance.............................................................. 4 Output Matching Considerations ............................................ 20 Typical Isolation Performance .................................................... 4 Output Biasing Considerations ................................................ 20 Absolute Maximum Ratings............................................................ 5 Input and Output Stability Considerations................................. 21 ESD Caution.................................................................................. 5 Local Oscillator Input Interface (LOIP, LOIM)..................... 22 Pin Configuration and Function Descriptions............................. 6 DC Coupling the LO.................................................................. 22 Simplified Interface Schematics ................................................. 7 A Step-by-Step Approach to Impedance Matching ............... 23 Typical Performance Characteristics ............................................. 8 Applications..................................................................................... 26 Receiver Characteristics .............................................................. 8 Downconverting Mixer ............................................................. 26 Transmit Characteristics............................................................ 13 Upconverting Mixer................................................................... 26 Circuit Description......................................................................... 15 Evaluation Board ............................................................................ 27 DC Interfaces .................................................................................. 16 Outline Dimensions ....................................................................... 32 Biasing and Decoupling (VPOS, DCPL)................................. 16 Ordering Guide .......................................................................... 32 REVISION HISTORY 11/06—Rev. A to Rev. B 3/02—Rev. 0 to Rev. A Changes to General Description .................................................... 1 Changes to Table 1............................................................................ 3 Changes to Table 3............................................................................ 4 Changes to Power-Down Interface (PWDN) Section ............... 16 Changes to Output Matching Considerations Section.............. 20 Changes to Circuit Description Section ...................................... 15 Changes to Output Matching Considerations ............................ 20 Changes to Upconverting Mixer Section .................................... 26 Changes to Table 6, Table 7, and Table 8 ..................................... 27 Changes to Figure 71 and Figure 72............................................. 29 Updated Outline Dimensions ....................................................... 32 Changes to Ordering Guide .......................................................... 32 Edits to Absolute Maximum Ratings ..............................................3 Edits to Input Interface (LOIP, LOIM) ........................................ 17 Edits to Table III ............................................................................. 22 Edits to Table IV ............................................................................. 23 Edits to Table V............................................................................... 23 Edits to Figure 23............................................................................ 23 Edits to Figure 24............................................................................ 23 6/00—Revision 0—Initial Version Rev. B | Page 2 of 32 AD8343 SPECIFICATIONS BASIC OPERATING INSTRUCTIONS VS = 5.0 V, TA = 25°C, unless otherwise noted. Table 1. Parameter INPUT INTERFACE (INPP, INPM) Differential Open Emitter DC Bias Voltage Operating Current Each Input (IO) Value of Bias Setting Resistor 1 Port Differential Impedance OUTPUT INTERFACE (OUTP, OUTM) Differential Open Collector DC Bias Voltage Voltage Swing Operating Current Each Output Port Differential Impedance LO INTERFACE (LOIP, LOIM) Differential Common Base Stage DC Bias Voltage 2 LO Input Power Port Differential Reflection Coefficient POWER-DOWN INTERFACE (PWDN) PWDN Threshold PWDN Response Time 3 PWDN Input Bias Current POWER SUPPLY Supply Voltage Range Total Quiescent Current Powered-Down Current Conditions/Comments Min Typ Max Unit Internally generated Current set by R3, R4; see Figure 72 1% bias resistors; R3, R4; see Figure 72 f = 50 MHz; R3 and R4 = 68.1 Ω; see Figure 57 1.1 5 1.2 17.6 68.1 5.6 + j 1.4 1.3 20 V mA Ω Ω Externally applied Collector bias (VS) = VPOS Same as input current f = 50 MHz; see Figure 60 4.5 1.65 5 VS ± 1 IO 900 − j 77 5.5 VS + 2 V V mA Ω Internally generated; (port is typically ac-coupled) 50 Ω impedance; see Figure 65 See Figure 64 300 −12 360 −10 −10 450 −3 mV dBm dB VS − 1.5 V V μs ns μA μA Assured on Assured off Time from device on to off; see Figure 52 Time from device off to on; see Figure 53 PWDN = 0 V (device on) PWDN = 5 V (device off ) VS − 0.5 2.2 500 −160 0 4.5 R3 and R4 = 68.1 Ω; see Figure 72 Over temperature VS = 5.5 V VS = 4.5 V Over temperature; VS = 5.5 V 1 5.0 50 20 6 50 −250 5.5 60 75 95 15 150 The balance in the bias current in the two legs of the mixer input is important to applications where a low feedthrough of the local oscillator (LO) is critical. This voltage is proportional to absolute temperature (PTAT). See the DC Coupling the LO section for more information regarding this interface. 3 Response time until device meets all specified conditions. 2 Rev. B | Page 3 of 32 V mA mA μA μA μA AD8343 TYPICAL AC PERFORMANCE VS = 5.0 V, TA = 25°C; see Figure 72, Table 6 through Table 8. Table 2. Input Frequency (MHz) Output Frequency (MHz) RECEIVER CHARACTERISTICS 400 70 900 170 1900 170 2400 170 2400 425 TRANSMITTER CHARACTERISTICS 150 900 150 1900 Conversion Gain (dB) SSB Noise Figure (dB) Input IP3 (dBm) Input 1 dB Compression Point (dBm) 5.6 3.6 7.1 6.8 5.4 10.5 11.4 14.1 15.3 16.2 20.5 19.4 16.5 14.5 16.5 3.3 3.6 2.8 2.1 2.2 7.5 0.25 17.9 16.0 18.1 13.4 1.9 0.8 TYPICAL ISOLATION PERFORMANCE VS = 5.0 V, TA = 25°C; see Figure 72, Table 6 through Table 8. Table 3. Input Frequency (MHz) Output Frequency (MHz) RECEIVER CHARACTERISTICS 400 70 900 170 1900 170 2400 170 2400 425 TRANSMITTER CHARACTERISTICS 150 900 150 1900 LO to Output Leakage (dBm) 2xLO to Output Leakage (dBm) 3xLO to Output Leakage (dBm) Input to Output Leakage (dBm) −40.1 −44.4 −65.6 −66.7 −51.1 −51.0 −35.5 −38.3 −44.4 −49.4 −44.0 <−75.0 −73.3 <−73.7 <−75.0 −62.4 −56.9 −65.7 −73.7 −92.3 −30 −25 −32 −17 −62 −65 −50 −40 Rev. B | Page 4 of 32 AD8343 ABSOLUTE MAXIMUM RATINGS Table 4. Parameter VPOS Quiescent Voltage OUTP, OUTM Quiescent Voltage INPP, INPM Voltage Differential (Either Polarity) LOIP, LOIM Current (Injection or Extraction) LOIP, LOIM Voltage Differential (Either Polarity) Internal Power Dissipation (TSSOP) 1 θJA (TSSOP) Maximum Junction Temperature Operating Temperature Range Storage Temperature Range Lead Temperature (Soldering 60 sec) 1 Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Rating 5.5 V 5.5 V 500 mV 1 mA 500 mV ESD CAUTION 320 mW 125°C/W 125°C −40°C to + 85°C −65°C to +150°C 300°C A portion of the device power is dissipated by external bias resistors, R3 and R4. Rev. B | Page 5 of 32 AD8343 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS COMM 1 14 COMM INPP INPM 3 (Not to Scale) 12 OUTM TOP VIEW 13 OUTP DCPL 4 11 COMM VPOS 5 10 LOIP PWDN 6 9 LOIM COMM 8 COMM 7 01034-002 AD8343 2 Figure 2. Pin Configuration Table 5. Pin Function Descriptions Pin No. 1, 7, 8, 11, 14 2 3 4 5 Mnemonic COMM INPP INPM DCPL VPOS 6 PWDN 9 10 12 13 LOIM LOIP OUTM OUTP Description Connect to low impedance circuit ground. Differential Input Pin. This pin needs to be dc-biased and typically ac-coupled; see Figure 3. Differential Input Pin. This pin needs to be dc-biased and typically ac-coupled; see Figure 3. Bias rail decoupling capacitor connection for LO driver; see Figure 6. Positive Supply Voltage (VS), 4.5 V to 5.5 V. Ensure adequate supply bypassing for proper device operation as shown in the Applications section. Power-Down Interface. Connect pin to ground for normal operating mode. Connect pin to supply for powerdown mode; see Figure 5. Differential Local Oscillator (LO) Input Pin. Typically ac-coupled; see Figure 4. Differential Local Oscillator (LO) Input Pin. Typically ac-coupled; see Figure 4. Open-Collector Differential Output Pin. This pin needs to be dc-biased and (usually) ac-coupled; see Figure 3. Open-Collector Differential Output Pin. This pin needs to be dc-biased and (usually) ac-coupled; see Figure 3. Rev. B | Page 6 of 32 AD8343 SIMPLIFIED INTERFACE SCHEMATICS OUTP OUTM 5VDC 5VDC LOIP VPOS 5VDC LOIM 1.2VDC 25kΩ PWDN BIAS CELL Figure 3. Input and Output Ports Figure 5. Power-Down Pin 2VDC DCPL VPOS VPOS 5VDC LOIM VBIAS 360mV DC 360mV DC LOIP 400Ω 400Ω LOIM 01034-004 LOIP Figure 4. LO Port BIAS CELL R1 10Ω 360mV DC 360mV DC LO BUFFER Figure 6. Bias Decoupling Pin Rev. B | Page 7 of 32 TO MIXER CORE 01034-006 INPM VPOS 5VDC 1.2VDC 01034-003 INPP 01034-005 VPOS 5VDC AD8343 TYPICAL PERFORMANCE CHARACTERISTICS RECEIVER CHARACTERISTICS fIN = 400 MHz, fOUT = 70 MHz, fLO = 330 MHz, see Figure 72, Table 6, and Table 8. 60 10 MEAN: 5.57dB 9 CONVERSION GAIN (dB) 40 30 20 7 6 5 01034-007 10 0 5.37 8 5.42 5.47 5.52 5.57 5.62 5.67 4 –40 5.72 01034-010 PERCENTAGE 50 –20 0 CONVERSION GAIN (dB) Figure 7. Gain Histogram; fIN = 400 MHz, fOUT = 70 MHz 80 23 MEAN: 20.5dBm 22 INPUT IP3 (dBm) 15 10 21 20 19 18 17 5 01034-008 16 15 –40 0 19.9 20.0 20.1 20.2 20.3 20.4 20.5 20.6 20.7 20.8 20.9 21.0 01034-011 PERCENTAGE 60 24 20 –20 0 20 40 60 80 TEMPERATURE (°C) INPUT IP3 (dBm) Figure 11. Input IP3 Performance Over Temperature; fIN = 400 MHz, fOUT = 70 MHz Figure 8. Input IP3 Histogram; fIN = 400 MHz, fOUT = 70 MHz 60 5.0 INPUT 1dB COMPRESSION POINT (dBm) MEAN: 3.31dB 50 45 40 35 30 25 20 15 01034-009 10 5 3.26 3.28 3.30 3.32 3.34 3.36 4.0 3.5 3.0 2.5 2.0 –40 3.38 –20 0 20 40 60 80 TEMPERATURE (°C) INPUT 1dB COMPRESSION POINT (dBm) Figure 9. Input 1 dB Compression Point Histogram; fIN = 400 MHz, fOUT = 70 MHz 4.5 01034-012 55 PERCENTAGE 40 Figure 10. Gain Performance Over Temperature; fIN = 400 MHz, fOUT = 70 MHz 25 0 3.24 20 TEMPERATURE (°C) Figure 12. Input 1 dB Compression Point Performance Over Temperature; fIN = 400 MHz, fOUT = 70 MHz Rev. B | Page 8 of 32 AD8343 fIN = 900 MHz, fOUT = 170 MHz, fLO = 730 MHz, see Figure 72, Table 6, and Table 8. 35 6 30 5 CONVERSION GAIN (dB) MEAN: 3.63dB 20 15 10 3 2 1 01034-013 5 0 3.40 4 3.45 3.50 3.55 3.60 3.65 3.70 3.75 3.80 0 –40 3.85 01034-016 PERCENTAGE 25 –20 0 CONVERSION GAIN (dB) 20 40 60 80 TEMPERATURE (°C) Figure 13. Gain Histogram; fIN = 900 MHz, fOUT = 170 MHz Figure 16. Gain Performance Over Temperature; fIN = 900 MHz , fOUT = 170 MHz 30 23 28 22 26 24 MEAN: 19.4dBm 21 INPUT IP3 (dBm) PERCENTAGE 22 20 18 16 14 12 10 8 20 19 18 17 6 0 18.2 18.4 18.6 18.8 19.0 19.2 19.4 19.6 19.8 20.0 20.2 20.4 15 –40 01034-017 16 01034-014 4 2 –20 0 INPUT IP3 (dBm) Figure 14. Input IP3 Histogram; fIN = 900 MHz, fOUT = 170 MHz 60 80 5.0 26 24 22 20 18 16 14 12 10 8 6 01034-015 4 2 3.54 3.56 3.58 3.60 3.62 3.64 3.66 3.68 3.70 4.0 3.5 3.0 2.5 2.0 –40 3.72 –20 0 20 40 60 80 TEMPERATURE (°C) INPUT 1dB COMPRESSION POINT (dBm) Figure 15. Input 1 dB Compression Point Histogram; fIN = 900 MHz, fOUT = 170 MHz 4.5 01034-018 INPUT 1dB COMPRESSION POINT (dBm) MEAN: 3.62dBm 28 PERCENTAGE 40 Figure 17. Input IP3 Performance Over Temperature; fIN = 900 MHz, fOUT = 170 MHz 30 0 3.52 20 TEMPERATURE (°C) Figure 18. Input 1dB Compression Point Performance Over Temperature; fIN = 900 MHz, fOUT = 170 MHz Rev. B | Page 9 of 32 AD8343 fIN = 1900 MHz, fOUT = 170 MHz, fLO = 1730 MHz, see Figure 72, Table 6, and Table 8. 10 28 26 MEAN: 7.09dB 24 9 CONVERSION GAIN (dB) 22 18 16 14 12 10 8 6 8 7 6 5 01034-019 4 2 4 –40 0 6.75 6.80 6.85 6.90 6.95 7.00 7.05 7.10 7.15 7.20 7.25 7.30 01034-022 PERCENTAGE 20 –20 0 MEAN: 16.54dBm INPUT IP3 (dBm) 25 20 15 15 14 13 12 11 01034-020 5 14.5 15.0 15.5 16.0 16.5 17.0 17.5 18.0 10 –40 18.5 01034-023 PERCENTAGE 16 30 10 –20 0 20 40 60 80 TEMPERATURE (°C) INPUT IP3 (dBm) Figure 23. Input IP3 Performance Over Temperature; fIN = 1900 MHz, fOUT = 170 MHz Figure 20. Input IP3 Histogram; fIN = 1900 MHz, fOUT = 170 MHz 5.0 40 35 30 25 20 15 01034-021 10 5 2.65 2.70 2.75 2.80 2.85 2.90 2.95 3.00 4.0 3.5 3.0 2.5 2.0 –40 3.05 –20 0 20 40 60 80 TEMPERATURE (°C) INPUT 1dB COMPRESSION POINT (dBm) Figure 21. Input 1 dB Compression Point Histogram; fIN = 1900 MHz, fOUT = 170 MHz 4.5 01034-024 MEAN: 2.8dBm 45 INPUT 1dB COMPRESSION POINT (dBm) 50 PERCENTAGE 80 17 35 0 2.60 60 18 45 0 14.0 40 Figure 22. Gain Performance Over Temperature; fIN = 1900 MHz, fOUT = 170 MHz Figure 19. Gain Histogram; fIN = 1900 MHz, fOUT = 170 MHz 40 20 TEMPERATURE (°C) CONVERSION GAIN (dB) Figure 24. Input 1 dB Compression Point Performance Over Temperature; fIN = 1900 MHz, fOUT = 170 MHz Rev. B | Page 10 of 32 AD8343 fIN = 2400 MHz, fOUT = 170 MHz, fLO = 2230 MHz, see Figure 72, Table 6, and Table 8. 40 35 10 MEAN: 6.79dB 9 CONVERSION GAIN (dB) 25 20 15 10 7 6 5 01034-025 5 0 5.8 8 6.0 6.2 6.4 6.6 6.8 7.0 7.2 7.4 4 –40 7.6 01034-028 PERCENTAGE 30 –20 0 CONVERSION GAIN (dB) Figure 25. Gain Histogram; fIN = 2400 MHz, fOUT = 170 MHz 16 INPUT IP3 (dBm) 20 15 15 14 13 12 11 01034-026 5 0 13.0 13.2 13.4 13.6 13.8 14.0 14.2 14.4 14.6 14.8 15.0 15.2 15.4 15.6 10 –40 01034-029 PERCENTAGE 80 17 MEAN: 14.46dBm 10 –20 0 INPUT IP3 (dBm) 20 40 60 80 TEMPERATURE (°C) Figure 26. Input IP3 Histogram; fIN = 2400 MHz, fOUT = 170 MHz Figure 29. Input IP3 Performance Over Temperature; fIN = 2400 MHz, fOUT = 170 MHz 3.0 INPUT: 2.11dBm 35 30 25 20 15 01034-027 10 5 1.95 2.00 2.05 2.10 2.15 2.20 2.25 2.30 2.35 2.0 1.5 1.0 0.5 0 –40 2.40 –20 0 20 40 60 80 TEMPERATURE (°C) INPUT 1dB COMPRESSION POINT (dBm) Figure 27. Input 1 dB Compression Point Histogram; fIN = 2400 MHz, fOUT = 170 MHz 2.5 01034-030 40 INPUT 1dB COMPRESSION POINT (dBm) 45 PERCENTAGE 60 18 25 0 1.90 40 Figure 28. Gain Performance Over Temperature; fIN = 2400 MHz, fOUT = 170 MHz 35 30 20 TEMPERATURE (°C) Figure 30. Input 1 dB Compression Point Performance Over Temperature; fIN = 2400 MHz, fOUT = 170 MHz Rev. B | Page 11 of 32 AD8343 fIN = 2400 MHz, fOUT = 425 MHz, fLO = 1975 MHz, see Figure 72, Table 6, and Table 8. 24 10 MEAN: 5.40dB 22 20 9 CONVERSION GAIN (dB) 16 14 12 10 8 6 4 7 6 01034-031 5 2 0 4.2 8 4.4 4.6 4.8 5.0 5.2 5.4 5.6 5.8 6.0 6.2 6.4 4 –40 6.6 01034-034 PERCENTAGE 18 –20 0 CONVERSION GAIN (dB) Figure 31. Gain Histogram; fIN = 2400 MHz, fOUT = 425 MHz 40 60 80 Figure 34. Gain Performance Over Temperature; fIN = 2400 MHz, fOUT = 425 MHz 22 18 MEAN: 16.50dBm 20 17 18 16 16 14 INPUT IP3 (dBm) PERCENTAGE 20 TEMPERATURE (°C) 12 10 8 15 14 13 6 12 01034-032 4 11 10 –40 18.0 17.8 17.6 17.4 17.2 17.0 16.8 16.6 16.4 16.2 16.0 15.8 15.6 15.4 15.2 15.0 14.8 0 01034-035 2 –20 0 65 60 80 3.0 50 45 40 35 30 25 20 15 01034-033 10 5 2.05 2.10 2.15 2.20 2.25 2.30 2.35 2.40 2.45 2.0 1.5 1.0 0.5 0 –40 2.50 INPUT 1dB COMPRESSION POINT (dBm) Figure 33. Input 1 dB Compression Point Histogram; fIN = 2400 MHz, fOUT = 425 MHz 2.5 01034-036 55 INPUT 1dB COMPRESSION POINT (dBm) MEAN: 2.22dBm 60 PERCENTAGE 40 Figure 35. Input IP3 Performance Over Temperature; fIN = 2400 MHz, fOUT = 425 MHz Figure 32. Input IP3 Histogram; fIN = 2400 MHz, fOUT = 425 MHz 0 2.00 20 TEMPERATURE (°C) INPUT IP3 (dBm) –20 0 20 40 60 80 TEMPERATURE (°C) Figure 36. Input 1 dB Compression Point Performance Over Temperature; fIN = 2400 MHz, fOUT = 425 MHz Rev. B | Page 12 of 32 AD8343 TRANSMIT CHARACTERISTICS fIN = 150 MHz, fOUT = 900 MHz, fLO = 750 MHz, see Figure 72, Table 6, and Table 7. 10 35 MEAN: 7.49dBm 9 CONVERSION GAIN (dB) 30 20 15 10 8 7 6 5 0 7.20 01034-037 5 7.25 7.30 7.35 7.40 7.45 7.50 7.55 7.60 7.65 4 –40 7.70 01034-040 PERCENTAGE 25 –20 0 20 40 60 80 TEMPERATURE (°C) CONVERSION GAIN (dB) Figure 40. Gain Performance Over Temperature; fIN = 150 MHz, fOUT = 900 MHz Figure 37. Gain Histogram; fIN = 150 MHz, fOUT = 900 MHz 24 20 MEAN: 18.1dBm 22 20 19 18 16 14 INPUT IP3 (dBm) 12 10 8 6 01034-038 01034-041 12 –40 INPUT IP3 (dBm) –20 0 20 40 60 80 TEMPERATURE (°C) Figure 38. Input IP3 Histogram; fIN = 150 MHz, fOUT = 900 MHz Figure 41. Input IP3 Performance Over Temperature; fIN = 150 MHz, fOUT = 900 MHz 24 3.0 MEAN: 1.9dBm INPUT 1dB COMPRESION (dBm) 20 18 16 14 12 10 8 6 4 01034-039 PERCENTAGE 15 13 18.45 18.40 18.35 18.30 18.25 18.20 18.15 18.10 18.05 18.00 17.95 17.90 17.80 17.85 2 22 16 14 4 0 17 2 2.0 1.5 1.0 0.5 0 –40 0 1.55 1.60 1.65 1.70 1.75 1.80 1.85 1.90 1.95 2.00 2.05 2.10 2.15 2.20 INPUT 1dB COMPRESSION POINT (dBm) Figure 39. Input 1 dB Compression Point Histogram; fIN = 150 MHz, fOUT = 900 MHz 2.5 01034-042 PERCENTAGE 18 –20 0 20 40 60 80 TEMPERATURE (°C) Figure 42. Input 1dB Compression Point Performance Over Temperature; fIN = 150 MHz, fOUT = 900 MHz Rev. B | Page 13 of 32 AD8343 fIN = 150 MHz, fOUT = 1900 MHz, fLO = 1750 MHz, see Figure 72, Table 6, and Table 7. 5 40 MEAN: 0.25dB 4 CONVERSION GAIN (dB) PERCENTAGE 30 25 20 15 10 0 –1.0 –0.8 –0.6 –0.4 –0.2 0 0.2 0.4 0.6 0.8 1.0 1.2 2 1 0 –1 01034-043 5 3 –2 –40 1.4 01034-046 35 –20 0 CONVERSION GAIN (dB) 20 40 60 80 TEMPERATURE (°C) Figure 43. Gain Histogram; fIN = 150 MHz, fOUT = 1900 MHz Figure 46. Gain Performance Over Temperature; fIN = 150 MHz, fOUT = 1900 MHz 50 18 MEAN: 13.4dBm 45 17 40 16 INPUT IP3 (dBm) 30 25 20 15 01034-044 13 12 10 0 10.5 11.0 11.5 12.0 12.5 13.0 13.5 14.0 14.5 15.0 15.5 16.0 16.5 17.0 9 –40 INPUT IP3 (dBm) 01034-047 5 –20 0 20 40 60 80 TEMPERATURE (°C) Figure 44. Input IP3 Histogram; fIN = 150 MHz, fOUT = 1900 MHz Figure 47. Input IP3 Performance Over Temperature; fIN = 150 MHz, fOUT = 1900 MHz 45 MEAN: 0.79dBm 35 30 25 20 15 10 01034-045 5 –0.5 0 0.5 1.0 1.5 2.0 2.5 3.0 INPUT 1dB COMPRESSION POINT (dBm) 2.0 40 PERCENTAGE 14 11 10 0 –1.0 15 1.0 0.5 0 –0.5 –1.0 –40 3.5 INPUT 1dB COMPRESSION POINT (dBm) Figure 45. Input 1 dB Compression Point Histogram; fIN = 150 MHz, fOUT = 1900 MHz 1.5 01034-048 PERCENTAGE 35 –20 0 20 40 60 80 TEMPERATURE (°C) Figure 48. Input 1 dB Compression Point Performance Over Temperature; fIN = 150 MHz, fOUT = 1900 MHz Rev. B | Page 14 of 32 AD8343 CIRCUIT DESCRIPTION The AD8343 is a mixer intended for high-intercept applications. The signal paths are entirely differential and dc-coupled to permit high-performance operation over a broad range of frequencies; the block diagram (see Figure 1) shows the basic functional blocks. The bias cell provides a PTAT (proportional to absolute temperature) bias to the LO driver and core. The LO driver consists of a three-stage limiting differential amplifier that provides a very fast (almost square-wave) drive to the bases of the core transistors. The AD8343 core utilizes a standard architecture where the signal inputs are directly applied to the emitters of the transistors in the cell (see Figure 49 and Figure 55). The bases are driven by the hard-limited LO signal that directs the transistors to steer the input currents into periodically alternating pairs of output terminals, thus providing the periodic polarity reversal that effectively multiplies the signal by a square wave of the LO frequency. COMM VPOS 5 1 7 8 11 14 AD8343 DCPL 4 PWDN 6 MIXER CORE BIAS Q1 Q2 13 OUTP 12 OUTM Q3 Q4 LO DRIVER 2 3 INPP INPM 01034-049 LOIP 10 LOIM 9 Unfortunately, practical implementations of analog multipliers generally make poor mixers because of imperfect linearity and the added noise that invariably accompanies attempts to improve linearity. The best mixers to date are those that use the LO signal to periodically reverse the polarity of the input signal. In this class of mixers, frequency conversion occurs as a result of multiplication of the signal by a square wave at the LO frequency. Because a square wave contains odd harmonics in addition to the fundamental, the signal is effectively multiplied by each frequency component of the LO. The output of the mixer therefore contains signals at FLO ± Fsig, 3×FLO ± Fsig, 5× FLO ± Fsig, 7×FLO ± Fsig, etc. The amplitude of the components arising from signal multiplication by LO harmonics falls off with increasing harmonic order because the amplitude of a square wave’s harmonics falls off. An example of this process is illustrated in Figure 50. The first pane of this figure shows an 800 MHz sinusoid intended to represent an input signal. The second pane contains a square wave representing an LO signal at 600 MHz which has been hard-limited by the internal LO driver. The third pane shows the time domain representation of the output waveform and the fourth pane shows the frequency domain representation. The two strongest lines in the spectrum are the sum and difference frequencies arising from multiplication of the signal by the LOs fundamental frequency. The weaker spectral lines are the result of the multiplication of the signal by various harmonics of the LO square wave. Figure 49. Topology SIGNAL To illustrate this functionality, when LOIP is positive, Q1 and Q4 are turned on, and Q2 and Q3 are turned off. In this condition, Q1 connects IINPP to OUTM and Q4 connects IINPM to OUTP. When LOIP is negative, the roles of the transistors reverse, steering IINPP to OUTP and IINPM to OUTM. Isolation and gain are possible because, at any instant, the signal passes through a common-base transistor amplifier pair. Multiplication is the essence of frequency mixing; an ideal multiplier would make an excellent mixer. The theory is expressed in the following trigonometric identity: LOCAL OSCILLATOR TIME DOMAIN SIG × LO FREQUENCY DOMAIN SIG × LO FREQUENCY Figure 50. Signal Switching Characteristics of the AD8343 Rev. B | Page 15 of 32 01034-050 5 × LO + SIG 7 × LO – SIG 5 × LO – SIG 3 × LO + SIG SIG + LO 3 × LO – SIG This states that the product of two sine-wave signals of different frequencies is a pair of sine waves at frequencies equal to the sum and difference of the two frequencies being multiplied. SIG – LO sin(ωsigt) × sin(ωLOt) = ½[cos(ωsigt − ωLOt) − cos(ωsigt + ωLOt)] AD8343 DC INTERFACES BIASING AND DECOUPLING (VPOS, DCPL) VPOS is the power supply connection for the internal bias circuit and the LO driver. Bypass this pin closely to GND with a capacitor in the range of 0.01 μF to 0.1 μF. The DCPL pin provides access to an internal bias node for noise bypassing purposes. Bypass this node to COMM with 0.1 μF. 1 POWER-DOWN INTERFACE (PWDN) The AD8343 is active when the PWDN pin is held low; otherwise the device enters a low-power state as shown in Figure 51. 01034-052 2 45 POWER-DOWN SWEPT FROM BOTH 3V TO 5V AND 5V TO 3V 40 DEVICE CURRENT (mA) 35 CH1 200nVΩ CH2 1.00VΩ M500ns CH2 4.48V Figure 52. PWDN Response Time Device On to Off 30 25 20 15 1 10 0 3.0 01034-051 5 3.5 4.0 4.5 5.0 2 01034-053 POWER-DOWN VOLTAGE (V) Figure 51. Device Current vs. PWDN Voltage To assure full power-down, the PWDN voltage must be within 0.5 V of the supply voltage at VPOS. Normal operation requires that the PWDN pin be taken at least 1.5 V below the supply voltage. The PWDN pin sources about 160 μA when pulled to GND (see the Pin Configuration and Function Descriptions section). It is not advised to leave the pin floating when the device is disabled; a resistive pull-up to VPOS is the minimum suggestion. M100ns CH2 4.48V Figure 53. PWDN Response Time Device Off to On TRIGGER HP8648C SIGNAL GENERATOR RF INPUT 1740MHz MATCHING NETWORK AND TRANSFORMER TEKTRONIX TDS694C OSCILLOSCOPE IF OUTPUT 170MHz AD8343 1 COMM COMM 14 2 INPP OUTP 13 3 INPM OUTM 12 4 DCPL COMM 11 5 VPOS LOIP 10 6 PWDN LOIM 9 7 COMM COMM 8 MATCHING NETWORK AND TRANSFORMER 0.1µF 1nH VPOS 0.1µF HP8130 PULSE GENERATOR TRANSFORMER LO INPUT 1570MHz HP8648C SIGNAL GENERATOR Figure 54. PWDN Response Time Test Schematic Rev. B | Page 16 of 32 01034-054 The AD8343 requires about 2.2 μs to turn off when PWDN is asserted; turn-on time is about 500 ns. Figure 52 and Figure 53 show typical characteristics (they vary with bypass component values). Figure 54 shows the test configuration used to acquire these waveforms. CH1 200nVΩ CH2 1.00VΩ AD8343 AC INTERFACES SINGLE-ENDED OUTPUT SIGNAL Because of the AD8343’s wideband design, there are several points to consider in its ac implementation; the basic ac signal connection diagram shown in Figure 55 summarizes these points. The input signal undergoes a single-ended to differential conversion and is then reactively matched to the impedance presented by the emitters of the core. The matching network also provides bias currents to these emitters. Similarly, the LO input undergoes a single-ended-to-differential transformation before it is applied to the 50 Ω differential LO port. The differential output signal currents appear at open-collectors and are reactively matched and converted to a single-ended signal. DIFFERENTIAL-TO-SINGLE-ENDED CONVERSION OUTPUT MATCHING NETWORK CORE BIAS NETWORK VPOS 6 10 9 1 8 11 14 AD8343 COMM DCPL PWDN 7 OUTP BIAS CELL OUTM 12 LOIP LOIM CORE LO DRIVER INPP 2 SINGLE-ENDED-TO-DIFFERENTIAL CONVERSION SINGLE-ENDED LO INPUT SIGNAL INPM 3 INPUT MATCHING NETWORK CORE BIAS NETWORK SINGLE-ENDED-TO-DIFFERENTIAL CONVERSION SINGLE-ENDED INPUT SIGNAL Figure 55. Basic AC Signal Connection Diagram Rev. B | Page 17 of 32 13 01034-055 4 5 AD8343 INPUT INTERFACE (INPP AND INPM) The AD8343 is designed to accept differential input signals for best performance. While a single-ended input can be applied, the signal capacity is reduced by 6 dB. Furthermore, there is no cancellation of even-order distortion arising from the nonlinear input impedances, so the effective signal handling capacity is reduced even further in distortion-sensitive situations. That is, the intermodulation intercepts are degraded. For these reasons, it is strongly recommended that differ ential signals be presented to the AD8343’s input. In addition to commercially available baluns, there are various discrete and printed circuit networks that can produce the required balanced waveforms and impedance match. These alternate circuits can be employed to possibly reduce the component cost of the mixer and/or improve performance. Baluns implemented in transmission line form (also known as common-mode chokes) are useful up to frequencies of around 1 GHz to 2 GHz, but are often excessively lossy at the higher frequencies that the AD8343 can handle. M/A-COM manufactures these baluns and Murata produces a true surface-mount balun. Coilcraft® and Toko are also manufacturers of RF baluns. INPUT MATCHING CONSIDERATIONS The design of the input matching network must be undertaken with two goals in mind: matching the source impedance to the input impedance of the AD8343 and providing a dc bias current path for the bias setting resistors. The maximum power transfer into the device occurs when there is a conjugate impedance match between the signal source and the input of the AD8343. This match is achieved with the differential equivalent of the classic L network, as illustrated in Figure 56. The figure gives two examples of the transformation from a single-ended L network to its differential counterpart. The design of L matching networks is adequately covered in texts on RF amplifier design (for example, Microwave Transistor Amplifiers by Guillermo Gonzalez). L1 caused by the change in Transistor re due to the change in current. The standard S parameter files are available through Analog Devices. 134Ω 68Ω 2500MHz 1500MHz 1000MHz 500MHz 50MHz FREQUENCY (50MHz TO 2500MHz) Figure 57. Input Differential Impedance (INPP, INPM) for Two Values of R3 and R4 Figure 57 provides a reasonable starting point for the design of the network. However, the particular board traces and pads transform the input impedance at frequencies in excess of about 500 MHz. For this reason, it is best to make a differential input impedance measurement at the board location where the matching network is installed, as a starting point for designing an accurate matching network. Differential impedance measurement is made relatively easy using a technique presented in an article by Lutz Konstroffer in RF Design, Vol. 22, January 1999, Page 24, 28; entitled “Finding the Reflection Coefficient of a Differential One-Port Device.” This article presents a mathematical formula for converting from a two-port single ended measurement to differential impedance. A full two-port measurement is performed using a vector network analyzer with Port 1 and Port 2 connected to the two differential inputs of the device at the desired measurement plane. The two-port measurement results are then processed with Konstroffer’s formula. This formula is straightforward and can be implemented through most RF design packages that can read and analyze network analyzer data. The Konstroffer formula is: Γs = L1/2 C2 L2 2C2 L2 2C2 SINGLE-ENDED DIFFERENTIAL (2 × S11 − S21)(1 − S22 − S12) + (1 − S11 − S21)(1 + S22 − 2 × S12) (2 − S21)(1 − S22 − S12 ) + (1 − S11 − S21)(1 + S22) This measurement can also be made using two ports of a 4-port vector network analyzer. This instrument, and accompanying software, is capable of directly producing differential measurements. C1 L1/2 01034-056 C1 01034-057 SINGLE-ENDED-TO-DIFFERENTIAL CONVERSION Figure 56. Single-Ended-to-Differential Transformation Figure 57 shows the differential input impedance of the AD8343 at the pins of the device. The two measurements shown in the figure are for two different core currents set by Resistor R3 and Resistor R4; the real value impedance shift is At low frequencies and IO = 16 mA, the differential input impedance seen at ports INPP and INPM of the AD8343 is low (~5 Ω in series with parasitic inductances that total about 3 nH). Because of this low value of impedance, it is beneficial to choose a transformer-type balun that can also perform all or part of the real value impedance transformation. The turns ratio of the transformer removes some of the matching burden from the differential L-network and should help lead to wider Rev. B | Page 18 of 32 AD8343 80 70 60 12 NOISE FIGURE 40 8 TOTAL SUPPLY CURRENT 30 20 4 GAIN 40 60 80 10 100 120 140 160 180 0 200 R3 AND R4 (Ω) Figure 58. Effect of R3 and R4 Value on Gain and Noise Figure 90 25 INPUT RF = 900MHz OUTPUT IF = 170MHz LO LOW SIDE INJECTION 20 60 15 50 40 10 TOTAL SUPPLY CURRENT 30 20 5 0 20 INPUT BIASING CONSIDERATIONS 80 70 INPUT IP3 10 P1dB 40 60 80 100 120 140 160 180 0 200 R3 AND R4 (Ω) The mixer core bias current of the AD8343 is adjustable from less than 5 mA to a safe maximum of 20 mA. It is important to note that the reliability of the AD8343 can be compromised for core currents set to higher than 20 mA. The AD8343 is tested to ensure that a value of 68.1 Ω ±1% ensures safe operation. Higher operating currents reduce distortion and affect gain, noise figure, and input impedance (Figure 58 and Figure 59). As the quiescent current is increased by a factor of N, the real part of the input impedance decreases by N. Assuming that a match is maintained, the signal current increases by √N, but the signal voltage decreases by √N, exercising a smaller portion of the nonlinear V–I characteristic of the common base connected mixer core transistors and results in lower distortion. At low frequencies where the magnitude of the complex input impedance is much smaller than the bias resistor values, adequate biasing can be achieved simply by connecting a resistor from each input to GND. The input terminals are internally biased at 1.2 V dc (nominal), so each resistor has a resistance 01034-058 0 20 50 TOTAL SUPPLY CURRENT (mA) 16 90 TOTAL SUPPLY CURRENT (mA) For more information on performing the input match, see the section entitled A Step-by-Step Approach to Impedance Matching. INPUT RF = 900MHz OUTPUT IF = 170MHz LO LOW SIDE INJECTION 01034-059 In cases where the use of a lossy balun is unavoidable, it can be worthwhile to perform simultaneous matching on both the input and output sides of the balun. The idea is to independently characterize the balun as a two-port device and then arrange a simultaneous conjugate match for it. Unfortunately, there seems to be no good way to determine the benefit this approach offers in any particular case; it remains necessary to characterize the balun and then design and simulate appropriate matching networks to make an optimal decision. One indication that such effort is worthwhile is the discovery that the adjustment of a post-balun-only matching network for best gain differs appreciably from that which produces best return loss at the baluns input. A better tactic is to try a different approach for the balun, either purchasing a different balun or designing a discrete network, for lower loss. 100 20 CONVERSION GAIN AND NOISE FIGURE (dB) In order to obtain the lowest distortion, the inputs of the AD8343 are driven through external ballast resistors. At low frequencies (up to perhaps 200 MHz), about 5 Ω per side is appropriate; above about 400 MHz, 10 Ω per side is better. The specified RF performance values for the AD8343 apply with these ballast resistors in use. These resistors improve linearity because their linear ac voltage drop partially swamps the nonlinear voltage swing occurring on the emitters. value calculated as RBIAS = 1.2/IBIAS. The resistor values should be well matched in order to maintain full LO to output isolation; 1% tolerance resistors are recommended. INPUT IP3 (dBm) AND P1dB (dBm) bandwidth matches. At frequencies above 1 GHz, the real part of the input impedance rises markedly and it becomes more attractive to use a 1:1 balun and rely on the L network for the entire impedance transformation. Figure 59. Effect of R3 and R4 Value on Input IP3 and Gain Compression At higher frequencies where the input impedance of the AD8343 rises, it is beneficial to insert an inductor in series between each bias resistor and the corresponding input pin in order to minimize signal shunting (Figure 72). Practical considerations limit the inductive reactance to a few hundred ohms. The best overall choice of inductor is the value that places the self-resonant frequency at about the upper end of the desired input frequency range. Note that there is an RF stability concern that argues in favor of erring on the side of too small an inductor value; see the Input and Output Stability Considerations section. The Murata LQW1608A series of inductors (0603 SMT package) offers values up to 56 nH before the self-resonant frequency falls below 2.4 GHz. For optimal LO-to-output isolation, it is important not to connect the dc nodes of the emitter bias inductors together in an attempt to share a single bias resistor. Doing so causes isolation degradation arising from VBE mismatches of the transistors in the core. Rev. B | Page 19 of 32 AD8343 OUTPUT INTERFACE (OUTP, OUTM) The output of the AD8343 comprises a balanced pair of open collector outputs. These should be biased to about the same voltage as is connected to VPOS. Connecting them to an appreciably higher voltage is likely to result in conduction of the ESD protection network on signal peaks, causing high distortion levels. On the other hand, setting the dc level of the outputs too low is also likely to result in poor device linearity due to collector-base capacitance modulation or saturation of the mixer core transistors. OUTPUT MATCHING CONSIDERATIONS The AD8343 requires a differential load for much the same reasons that the input needs a differential source to achieve optimal device performance. In addition, a differential load provides the best LO to output isolation and the best input to output isolation. At low output frequencies, it is usually not appropriate to arrange a conjugate match between the device output and the load, even though doing so maximizes the small signal conversion gain. This is because the output impedance at low frequencies is quite high (a high resistance in parallel with a small capacitance). See Figure 60 for a plot of the differential output impedance measured at the device pins. This data is available in standard file format at the Analog Devices website (http://www.analog.com); search for AD8343, then click on AD8343 S-Parameters. If a matching high impedance load is used, sufficient output voltage swing occurs to cause output clipping even at relatively low input levels, constituting a loss of dynamic range. The linear range of voltage swing at each output pin is about ±1 V from the supply voltage VPOS. A good compromise is to provide a load impedance of about 200 Ω to 500 Ω between the output pins at the desired output frequency (based on 15 mA to 20 mA bias current at each input). At output frequencies below 500 MHz, more output power can be obtained before the onset of gross clipping by using a lower load impedance; however, both gain and low order distortion performance can be degraded. FREQUENCY (50MHz TO 2500MHz) 50MHz The output load impedance must also be kept reasonably low at the image frequency to avoid developing appreciable extra voltage swing, which can reduce dynamic range. If maintaining a good output return loss is not required, a 4:1 to 8:1 (impedance) flux-coupled transformer can be used to present a suitable load to the device and to provide collector bias via a center tap as shown in Figure 69. At all but the lowest output frequencies, it becomes desirable to tune out the output capacitance of the AD8343 by connecting an inductor between the output pins. On the other hand, when a good output return loss is desired, the output can be resistively loaded with a shunt resistance between the output pins in order to set the real value of output impedance. With selection of both the transformer’s impedance ratio and the shunting resistance as required, the desired total load (~500 Ω) is achieved while optimizing both signal transfer and output return loss. At higher output frequencies, the output conductance of the device becomes higher (see Figure 60), with the consequence that above about 900 MHz, it does become appropriate to perform a conjugate match between the load and the AD8343s output. The device’s own output admittance becomes sufficient to remove the threat of clipping from excessive voltage swing. Just as for the input, it is best to perform differential output impedance measurements on the board layout to effectively develop a good matching network. OUTPUT BIASING CONSIDERATIONS When the output single-ended-to-differential conversion takes the form of a transformer whose primary winding is center tapped, simply apply VPOS to the tap, preferably through a ferrite bead in series with the tap in order to avoid a common mode instability problem (see the Input and Output Stability Considerations section). See Figure 69 for an example of this network. The collector dc bias voltage must be nominally equal to the supply voltage applied to Pin 5 (VPOS). If a 1:1 transmission line balun is used for the output, it is necessary to bring in collector bias through separate inductors. These inductors are chosen to obtain a high impedance over the RF output frequency range of interest. See Figure 70 for an example of this network. 500MHz 1500MHz 1000MHz 01034-060 2000MHz Figure 60. Output Differential Impedance (OUTP, OUTM) Rev. B | Page 20 of 32 AD8343 INPUT AND OUTPUT STABILITY CONSIDERATIONS The differential configuration of the input and output ports of the AD8343 raises the need to consider both differential and common-mode RF stability of the device. Throughout the following stability discussion, common mode is used to refer to a signal that is referenced to ground. The equivalent commonmode impedance is the value of impedance seen from the node under discussion to ground. The book, Microwave Transistor Amplifiers by Guillermo Gonzalez, also has an excellent section covering stability of amplifiers. FREQUENCY: 50MHz TO 2500MHz INCREMENT: 100MHz 01034-062 50MHz Figure 62. Common-Mode Output Stability Circles 4-PORT NETWORK ANALYZER The plotted stability circles in Figure 62 indicate that the guiding principle for preventing stability problems due to commonmode output loading is to avoid high-Q common-mode inductive loading. This stability concern is of particular importance when the output is taken from the device with a center-tapped transformer. The common-mode inductance to the center tap arises from imperfect coupling between the halves of the primary winding and produces an unstable common-mode loading condition. Fortunately, a simple solution is to insert a ferrite bead in series with the center tap, then provide effective RF bypassing on the power supply side of the bead. The bead develops substantial impedance (tens of ohms) by the time a frequency of about 200 MHz is reached. The Murata BLM21P300S is a possible choice for many applications. S PARAMETER TEST SET BIAS BIAS BIAS BIAS TEE TEE TEE TEE AD8343 1 COMM 0.1µF 1nH VPOS 0.1µF COMM 14 2 INPP OUTP 13 3 INPM OUTM 12 4 DCPL COMM 11 5 VPOS LOIP 10 6 PWDN LOIM 9 7 COMM COMM 8 01034-063 The AD8343 is unconditionally stable for any differential impedance, so device stability need not be considered with respect to the differential terminations. However, the device is potentially unstable (k factor is less than one) for some commonmode impedances. Figure 61 and Figure 62 plot the input and output common-mode stability regions, respectively. Figure 63 shows the test equipment configuration to measure these stability circles. 150MHz Figure 63. Impedance and Stability Circle Test Schematic In cases where a transmission line balun is used at the output, the solution deserves a bit more exploration. After the differential impedance matching network is designed, it is possible to measure or simulate the common-mode impedance seen by the device. This impedance is plotted against the stability circles to ensure stable operation. An alternate topology for the matching network is required if the proposed network produces an unacceptable common-mode impedance. 50MHz 01034-061 150MHz FREQUENCY: 50MHz TO 2500MHz INCREMENT: 100MHz Figure 61. Common-Mode Input Stability Circles Rev. B | Page 21 of 32 AD8343 5 4 CONVERSION GAIN 3 15 2 10 NOISE FIGURE NOISE FIGURE (dB) 20 1 5 0 –40 –30 –20 01034-065 LOCAL OSCILLATOR INPUT INTERFACE (LOIP, LOIM) 0 –10 LO POWER (dBm) The LO terminals of the AD8343 are internally biased; connections to these terminals should include dc blocks, except as noted below in the DC Coupling the LO section. Figure 65. Gain and Noise Figure vs. LO Input Power DC COUPLING THE LO The differential LO input return loss (with a 50 Ω differential input impedance) is presented in Figure 64. As shown, this port has a typical differential return loss of better than 9.5 dB (2:1 V SWR). If better return loss is desired for this port, differential matching techniques can also be applied. 0 –5 –10 –15 The AD8343’s LO limiting amplifier chain is internally dc-coupled. In some applications or experimental situations, it is useful to exploit this property. Following is the recommended way to do so. The LO pins are internally biased at about 360 mV with respect to COMM. Driving the LO to either extreme requires injecting several hundred microamps into one LO pin and extracting about the same amount of current from the other. The incremental impedance at each pin is about 25 Ω, so the voltage level on each pin is disturbed very little by the application of external currents in that range. Figure 66 illustrates how to drive the LO port with continuous dc and also from standard ECL powered by –5.2 V. –20 2000 2500 4 13kΩ 6 BIAS Figure 64. LO Input Differential Reflection Coefficient At low LO frequencies, it is reasonable to drive the AD8343 with a single-ended LO, connecting the undriven LO pin to GND through a dc block. This results in an LO input impedance closer to 25 Ω at low frequencies, which should be factored into the design. At higher LO frequencies, differential drive is strongly recommended. 10 9 14 AD8343 DCPL PWDN 11 LOIP COMM OUTP 1500 8 13 12 OUTM 1000 FREQUENCY (50MHz TO 2500MHz) 7 LOIM LO DRIVER 1kΩ 2 INPP 3 INPM +5V 3.6kΩ The suggested minimum LO power level is about –12 dBm. This can be seen in Figure 65. VPOS 3.6kΩ 5 1 4 6 11 14 AD8343 DCPL PWDN 13 BIAS 12 ECL 390Ω 1.2kΩ 10 ECL 1.2kΩ 390Ω 8 COMM –5.2V –5.2V 7 9 LOIP LOIM LO DRIVER 2 INPP –5.2V Figure 66. DC Interfaces to the LO Port Rev. B | Page 22 of 32 OUTP 500 1 OUTM 0 5 3 INPM 01034-066 –30 VPOS CONTINUOUS DC –25 01034-064 REFLECTION COEFFICIENT (dB) 25 INPUT RF = 900MHz OUTPUT IF = 170MHz LO LOW SIDE INJECTION CONVERSION GAIN (dB) For the device input, capacitive common-mode loading tends to produce an unstable circuit, particularly at low frequencies (see Figure 61). Fortunately, either type of single-ended-to-differential conversion (transmission line balun or flux-coupled transformer) tends to produce inductive loading, although some matching network topologies and/or component values circumvent this desirable behavior. In general, a simulation of the commonmode termination seen by the AD8343’s input port is plotted against the input stability circles to check stability. This is especially recommended if the single-ended-to-differential conversion is done with a discrete component circuit. AD8343 A STEP-BY-STEP APPROACH TO IMPEDANCE MATCHING Measure AD8343 Differential Impedance at Location of First Matching Component The following discussion addresses, in detail, the matter of establishing a differential impedance match to the AD8343. This section specifically deals with the input match, and the use of Side A of the evaluation board (Figure 71). An analogous procedure is used to establish a match to the output if desired. Once the target impedance is established, the next step in matching to the AD8343 is to measure the differential impedance at the location of the first matching component. The A side of the evaluation board is designed to facilitate doing so. Circuit Setup The AD8343 must be powered up, driven with LO; its outputs are terminated in a manner that avoids the common-mode stability problem, as discussed in the Input and Output Stability Considerations section. A convenient way to deal with the output termination is to place ferrite chokes at L3A and L4A and omit the output matching components altogether. It is also important to establish the means of providing bias currents to the input pins because this network can have unexpected loading effects and inhibit matching progress. After the calibration is complete, connect Network Analyzer Port 1 and Network Analyzer Port 2 to the differential inputs of the AD8343 Evaluation Board. Establish Target Impedance This step is necessary when the single-ended-to-differential network (input balun) does not produce a 50 Ω output impedance. In order to provide for maximum power transfer, the input impedance of the matching network, loaded with the AD8343 input impedance (including ballast resistors), is the conjugate of the output impedance of the single-ended-todifferential network. This step is of particular importance when utilizing transmission line baluns because the differential output impedance of the input balun can differ significantly from what is expected. Therefore, it is a good idea to make a separate measurement of this impedance at the desired operating frequency before proceeding with the matching of the AD8343. The idea is to make a differential measurement at the output of the balun, with the single-ended port of the balun terminated in 50 Ω. Again, there are two methods available for making this measurement: use of the ATN multiport network analyzer to measure the differential impedance directly, or use of a standard two-port network analyzer and Konstroffer’s transformation equation. In order to utilize a standard two-port analyzer, connect the two ports of the calibrated vector network analyzer (VNA) to the balanced output pins of the balun, measure the two-port S parameters, then use Konstroffer’s formula to convert the twoport parameters to one-port differential Γ: Γs = Before doing the board measurements, it is necessary to perform a full two-port calibration of the VNA at the ends of the cables that are used to connect to the board’s input connectors, using the SOLT (Short, Open, Load, Thru) method or equivalent. It is a good idea to set the VNAs sweep span to a few hundred megahertz or more for this work because it is often useful to see what the circuit is doing over a large range of frequencies, not just at the intended operating frequency. This is particularly useful for detecting stability problems. (2 × S11 − S21)(1 − S22 − S12 ) + (1 − S11 − S21)(1 + S22 − 2 × S12 ) (2 − S21)(1 − S22 − S12 ) + (1 − S11 − S21)(1 + S22 ) On the AD8343 evaluation board, it is necessary to temporarily install jumpers at Z1A and Z3A if Z4A is the desired component location. 0 Ω resistors or capacitors of sufficient value to exhibit negligible reactance work nicely for this purpose. Next, extend the reference plane to the location of your first matching component. This is accomplished by solidly shorting both pads at the component location to GND Power to the board must be off for this operation. Adjust the VNA reference plane extensions to make the entire trace collapse to a point (or best approximation thereof near the desired frequency) at the zero impedance point of the Smith Chart. Do this for each port. A reasonable way to provide a good RF short is to solder a piece of thin copper or brass sheet on edge across the pads to the nearby GND pads. Now, remove the short, apply power to the board, and take readings. Look at both S11 and S22 to verify that they remain inside the unit circle of the Smith Chart over the whole frequency range being swept. If they fail to do so, this is a sign that the device is unstable (perhaps due to an inappropriate commonmode load) or that the network analyzer calibration is wrong. Either way, the problem must be addressed before proceeding further. Assuming that the values look reasonable, use Konstroffer’s formula to convert to differential Γ. Design the Matching Network Perform a trial design of a matching network utilizing standard impedance matching techniques. The network can be designed using single-ended network values, and then converted to differential form as illustrated in Figure 56. Figure 67 shows a theoretical design of a Series C/Shunt C L-network applied between 50 Ω and a typical load at 1.8 GHz. Rev. B | Page 23 of 32 AD8343 1.0 0.5 2.0 1 2.9pF SHUNT CAPACITOR 3.3pF SHUNT CAPACITOR 0.2 5mm 50Ω TRACE 5.0 2 0.5 1.0 2.0 5.0 01034-067 0.2 0.5 1.0 2.0 0 5.0 FREQUENCY = 1.8GHz Figure 67. Theoretical Design of Matching Network 01034-068 0.2 Figure 68. Effect of 50 Ω PCB Trace on 50 Ω Real Impedance Load This theoretical design is important because it establishes the basic topology and the initial matching value for the network. The theoretical value of 2.9 pF for the initial matching component is not available in standard capacitor values, so a 3.0 pF is placed in the first shunt-matching location. This value can prove to be too large, causing an overshoot of the 50 Ω real impedance circle, or too small, causing the opposite effect. Always keep in mind that this is a measure of differential impedance. The value of the capacitor must be modified to achieve the desired 50 Ω real impedance. However, it occasionally happens that the inserted shunt capacitor moves the impedance in completely unexpected and undesired ways. This is almost always an indication that the reference plane was improperly extended for the measurement. Readjust the reference planes and attempt the shunt capacitor match with another calculated value. When a differential impedance of 50 Ω (real part) is achieved, the board must be powered down and then another short is placed on the board in preparation for resetting the port extensions to a new reference plane location. Place this short where the next series components are expected to be added, and it is important that both Port 1 and Port 2 be extended to this point on the board. Another differential measurement must be taken at this point to establish the starting impedance value for the next matching component. Note that if 50 Ω PCB traces of finite length are used to connect pads, the impedance experiences an angular rotation to another location on the Smith Chart as indicated in Figure 68. With the reference plane extended to the location of the series matching components, it is now necessary to readjust the shunt capacitance value to achieve the desired 50 Ω real impedance. However, this rotation is not very noticeable if the board traces are fairly short or the application frequency is low. As before, calculate the series capacitance value required to move in the direction shown as step two in Figure 67. Choose the nearest standard component remembering to perform the differential conversion, and install on the board. Again, if any unexpected impedance transformations occur the reference planes were probably extended incorrectly making it necessary to readjust these planes. This value of series capacitance adjusts to obtain the desired value of differential impedance. These steps apply to any of the previously discussed matching topologies suitable for the AD8343. Also, if a target impedance other than 50 Ω is required, simply calculate and adjust the components to obtain the desired load impedance. If the matching network topology requires a differential shunt inductor between the inputs, it is necessary to place a series blocking capacitor of low reactance in series with the inductor to avoid creating a low resistance dc path between the input terminals of the AD8343. Failure to heed this warning results in very poor LO-output isolation. Transfer the Matching Network to the Final Design On the B side of the AD8343 evaluation board, install the matching network and the input balun. Install the same output network as used for the work on the A side, then power up the board and measure the input return loss at the RF input connector on the board. Strictly speaking, the above procedure (if carried out accurately) for matching the AD8343 obtains the best conversion gain. This differs materially from the condition that results in best return loss at the board’s input if the balun is lossy. Rev. B | Page 24 of 32 AD8343 If the result is not as expected, the balun is probably producing an unexpected impedance transformation. If the performance is extremely far from the desired result and it was assumed that the output impedance of the balun was 50 Ω, it is necessary to measure the output impedance of the balun in question. The design process must be repeated using the baluns output impedance instead of 50 Ω as the target. However, if the performance is close to the desired result it is possible to tweak the values of the matching network to achieve a satisfactory outcome. These changes begin with a change from one standard value to the adjacent standard value. With these minor modifications to the matching network, one is able to evaluate the trend required to reach the desired result. If the result is unsatisfactory and an acceptable compromise cannot be reached by further adjustment of the matching network, there are two options: obtain a better balun, or attempt a simultaneous conjugate match to both ports of the balun. Accomplishing the latter (or even evaluating the prospects for useful improvement) requires obtaining full two-port, singleended-to-differential S parameters for the balun, and requires the use of the ATN 4000 or a similar multiport network analyzer test set. Gonzalez presents formulas for calculating the simultaneous conjugate match in his book, Microwave Transistor Amplifiers. At higher frequencies, the measurement process described above becomes increasingly corrupted by unaccounted for impedance transformations occurring in the traces and pads between the input connectors and the extended reference plane. One approach to dealing with this problem is to access the desired measurement points by soldering down semirigid coaxial cables that have been connected to the VNA and directly calibrated at the free ends. Rev. B | Page 25 of 32 AD8343 APPLICATIONS DOWNCONVERTING MIXER A typical downconversion application is shown in Figure 69 with the AD8343 connected as a receive mixer. The input single-ended-to-differential conversion is obtained through the use of a 1:1 transmission line balun. The input matching network is positioned between the balun and the input pins, while the output is taken directly from a 4:1 impedance ratio (2:1 turns ratio) transformer. The local oscillator signal at a level of –12 dBm to –3 dBm is brought in through a second 1:1 balun. VPOS 4.71Ω 11 AD8343 6 1:1 10 9 DCPL PWDN 4:1 13 BIAS FB IFOUT 12 OUTM 4 VPOS 14 LOIP FERRITE BEAD The output frequency is assumed to be high enough that conjugate matching to the output of the AD8343 is desirable, so the goal of the matching network is to provide a conjugate match between the device’s output and the differential input of the output balun. LOIM L1A 2 R1A ˜68Ω 1:1 INPP 3 INPM L1B R1B Z1 Z2A In this example, the output signal is taken via a differential matching network comprising Z3 and Z4A/Z4B, then through the 1:1 balun and dc blocking capacitors to the single-ended output. ˜68Ω Z2B 01034-069 RFIN Figure 69. Typical Downconversion Application R1A and R1B set the core bias current of 18.5 mA per side. L1A and L1B provide the RF choking required to avoid shunting the signal. Z1, Z2A, and Z2B comprise a typical input matching network that is designed to match the AD8343s differential input impedance to the differential output impedance of the balun. The IF output is taken through a 4:1 (impedance ratio) transformer that reflects a 200 Ω differential load to the collectors. This output coupling arrangement is reasonably broadband, although in some cases the user might want to consider adding a resonator tank circuit between the collectors to provide a measure of IF selectivity. The ferrite bead (FB), in series with the output transformer’s center tap, addresses the commonmode stability concern. In this circuit, the PWDN pin is shown connected to GND, enabling the mixer. In order to enter power-down mode and conserve power, the PWDN pin must be taken within 500 mV of VPOS. The DCPL pin is bypassed to GND with about 0.1 μF. Failure to do so results in a higher noise level at the output of the device. This circuit uses shunt feed to provide collector bias for the transistors because the output balun in this circuit has no convenient center-tap. The ferrite beads, in series with the output’s bias inductors, provide some small degree of damping to ease the common-mode stability problem. Unfortunately, this type of output balun can present a common-mode load that enters the region of output instability, so most of the burden of avoiding overt instability falls on the input circuit, presenting an inductive common-mode termination over as broad a band of frequencies as possible. The PWDN pin is shown as tied to GND, enabling the mixer. The DCPL pin must be bypassed to GND with about 0.1 μF to bypass noise from the internal bias circuit. VPOS 0.1µF VPOS 4 6 0.1µF 10 9 0.1µF 5 1 7 8 11 14 AD8343 COMM 0.1µF LO IN VPOS DCPL PWDN FB Z4A 13 BIAS RFOUT Z3 Z4B 12 LOIP FB LOIM LO DRIVER 2 RFIN INPP VPOS 3 INPM Z2A Z1 UPCONVERTING MIXER Z2B A typical upconversion application is shown in Figure 70. Both the input and output single-ended-to-differential conversions Rev. B | Page 26 of 32 R1A R1B Figure 70. Typical Upconversion Application 01034-070 8 OUTP 7 R1A and R1B set the core bias current of 18 mA per side. Z1, Z2A, and Z2B comprise a typical input matching network designed to match the AD8343s differential input impedance to the differential output impedance of the balun. It is assumed for this example that the input frequency is low and that the magnitude of the device’s input impedance is therefore much smaller than the bias resistor values, allowing the input bias inductors to be eliminated with very little penalty in gain or noise performance. OUTM 1 COMM 0.1µF LO IN –10dBm 5 OUTP VPOS are obtained through the use of 1:1 transmission line baluns. The differential input and output matching networks are designed between the balun and the I/O pins of the AD8343. The local oscillator signal at a level of –12 dBm to –3 dBm is brought in through a third 1:1 balun. AD8343 EVALUATION BOARD The following tables delineate the components used for the characterization procedure used to generate Figure 7 through Figure 48 and most other data contained in this data sheet. Table 6 lists the support components that are delivered with the AD8343 evaluation board. Note that the board is shipped without any frequency specific components installed. Table 7 lists the components used to obtain the frequency selection necessary for the product receiver evaluation, and Table 8 lists the transmitter evaluation components. The AD8343 evaluation board has two independent areas, denoted A and B. The circuit schematics are shown in Figure 71 and Figure 72. An assembly drawing is included in Figure 73 to ease identification of components, and representations of the board layout are included in Figure 74 through Figure 77. The A region is configured for ease in making device impedance measurements as part of the process of developing suitable matching networks for a final application. The B region is designed for operating the AD8343 in a single-ended application environment and therefore includes pads for attaching baluns or transformers at both the input and output. Table 6. Values of Support Components Shipped with Evaluation Board and Used for Device Characterization Component Designator C1A, C1B, C3A, C3B, C11A, C11B C2A, C2B, C4A, C4B, C5A, C5B, C6A, C6B, C9A, C9B, C10A, C10B, C12A, C12B, C13A, C13B R3A, R3B, R4A, R4B R1A, R1B, R2A, R2B R5A, R5B J1A, J1B T1A, T1B, T2B (Various) T3B (Various) R6A, R6B, R7A, R7B L1A, L1B, L2A, L2B Value 0.1 μF 0.01 μF Quantity 6 16 Manufacturer/Part Number Murata Murata 68.1 Ω ± 1% 3.9 Ω ± 5% 0Ω Ferrite Bead 1:1 4:1 10 Ω ± 1% 56 nH 4 4 2 2 3 1 4 4 Panasonic Panasonic Panasonic Murata M/A-COM ETC1-1-13 Wideband Balun Mini-Circuits® TC4-1W Transformer Panasonic Panasonic Table 7. Values of Matching Components Used for Transmitter Characterization Component Designator fIN = 150 MHz, fOUT = 900 MHz T1B, T3B T2B R6B, R7B Z1B, Z3B Z2B Z5B, Z7B Z8B L1B, L2B L3B, L4B Z4B, Z6B, Z9B—Not Populated fIN = 150 MHz, fOUT = 1900 MHz T1B, T3B T2B R6B, R7B Z1B, Z3B Z2B Z5B, Z7B Z8B L1B, L2B L3B, L4B Z4B, Z6B, Z9B—Not Populated Value Quantity Manufacturer/Part Number 1:1 1:1 5.1 Ω 8.2 nH 33 pF 8.2 nH 6.2 pF 56 nH 150 nH 2 1 2 2 1 2 1 2 2 M/A-COM ETC1-1-13 Wideband Balun Mini-Circuits ADTL1-18-75 Panasonic Murata Murata Murata Murata Panasonic Murata 1:1 1:1 5.1 Ω 8.2 nH 33 pF 1.8 nH 1.8 pF 56 nH 68 nH 2 1 2 2 1 2 1 2 2 M/A-COM ETC1-1-13 Wideband Balun Mini-Circuits ADTL1-18-75 Panasonic Murata Murata Murata Murata Panasonic Murata Rev. B | Page 27 of 32 AD8343 Table 8. Values of Matching Components Used for Receiver Characterization Component Designator fIN = 400 MHz, fOUT = 70 MHz T1B, T2B T3B R6B, R7B Z1B, Z3B Z2B Z5B, Z7B Z6B L1B, L2B Z4B, Z8B, L3B, L4B, Z9B—Not Populated fIN = 900 MHz, fOUT = 170 MHz T1B, T2B T3B R6B, R7B Z1B, Z3B Z4B Z5B, Z7B Z6B L1B, L2B Z2B, Z8B, L3B, L4B, Z9B—Not Populated fIN = 1900 MHz, fOUT = 425 MHz T1B, T2B T3B R6B, R7B Z1B, Z3B Z2B Z5B, Z7B Z8B L1B, L2B Z6B, Z4B, L3B, L4B, Z9B—Not Populated fIN = 1900 MHz, fOUT = 170 MHz T1B, T2B T3B R6B, R7B Z1B, Z3B Z4B Z5B, Z7B Z6B L1B, L2B Z2B, Z8B, L3B, L4B, Z9B—Not Populated Value Quantity Manufacturer/Part Number 1:1 4:1 10 Ω 0Ω 8.2 pF 150 nH 3.4 pF 56 nH 2 1 2 2 1 2 1 2 M/A-COM TC1-1-13 Wideband Balun Mini-Circuits TC4-1W Transformer Panasonic Panasonic Murata Murata Murata Panasonic 1:1 4:1 10 Ω 0Ω 3.0 pF 120 nH 0.4 pF 56 nH 2 1 2 2 1 2 1 2 M/A-COM ETC1-1-13 Wideband Balun Mini-Circuits TC4-1W Transformer Panasonic Panasonic Murata Murata Murata Panasonic 1:1 4:1 10 Ω 6.8 nH 0.6 pF 39 nH 2.0 pF 56 nH 3 1 2 2 1 2 1 2 M/A-COM ETC1-1-13 Wideband Balun Mini-Circuits TC4-1W Transformer Panasonic Murata Murata Murata Murata Panasonic 1:1 4:1 10 Ω 6.8 nH 0.5 pF 100 nH 2.4 pF 56 nH 2 1 2 2 1 2 1 2 M/A-COM ETC1-1-13 Wideband Balun Mini-Circuits TC4-1W Transformer Panasonic Murata Murata Murata Murata Panasonic Rev. B | Page 28 of 32 AD8343 R2A VPOS_A R1A C1A GND_A C3A C2A C4A J1A DUTA C7A AD8343 PWDN_1_A C5A Z1A R6A 1 COMM COMM 14 2 INPP OUTP 13 3 INPM OUTM 12 L3A Z2A Z4A R7A INPUT_M_A C6A Z3A L1A Z9A 4 DCPL COMM 11 5 VPOS LOIP 10 OUTPUT_P_A Z6A C8A C11A L2A C9A Z5A INPUT_P_A Z8A OUTPUT_M_A L4A Z7A C10A C12A R3A R4A PWDN_A 6 PWDN 7 COMM COMM 8 3 LOIM 9 LO INPUT_A 2 4 T1A C13A 5 1 01034-071 R5A NOTES 1. REFERENCE TABLE 6 FOR COMPONENT VALUES AS SHIPPED. 2. REFERENCE TABLE 6, 7, AND 8 FOR CHARACTERIZATION VALUES. Figure 71. Characterization and Evaluation Board Circuit A R2B VPOS_B R1B GND_B C1B C3B DUTB PWDN_1_B C7B AD8343 C5B INPUT_B Z1B T2B 5 4 C6B 2 3 L3B 1 COMM COMM 14 R6B 1 Z2B C4B J1B C2B Z4B R7B Z3B L1B L2B R3B R4B 2 INPP OUTP 13 3 INPM OUTM 12 C11B 4 DCPL COMM 11 5 VPOS LOIP 10 T3B C9B 6 1 Z5B Z9B Z6B Z8B 3 C8B L4B Z7B OUTPUT_B 2 4 C10B C12B 6 PWDN PWDN_B R5B LOIM 9 3 C13B LO_INPUT_B 2 4 T1B 1 5 7 COMM COMM 8 01034-072 NOTES 1. REFERENCE TABLE 6 FOR COMPONENT VALUES AS SHIPPED. 2. REFERENCE TABLE 6, 7, AND 8 FOR CHARACTERIZATION VALUES. ASSEMBLY TOP ASSEMBLY BOTTOM Figure 73. Evaluation Board Assembly Drawing Rev. B | Page 29 of 32 01034-073 Figure 72. Characterization and Evaluation Board Circuit B 01034-074 AD8343 01034-075 Figure 74. Evaluation Board Artwork Top Figure 75. Evaluation Board Artwork Internal 1 Rev. B | Page 30 of 32 01034-076 AD8343 01034-077 Figure 76. Evaluation Board Artwork Internal 2 Figure 77. Evaluation Board Artwork Bottom Rev. B | Page 31 of 32 AD8343 OUTLINE DIMENSIONS 5.10 5.00 4.90 14 8 4.50 4.40 4.30 6.40 BSC 1 7 PIN 1 1.05 1.00 0.80 0.65 BSC 1.20 MAX 0.15 0.05 0.30 0.19 0.20 0.09 SEATING COPLANARITY PLANE 0.10 8° 0° 0.75 0.60 0.45 COMPLIANT TO JEDEC STANDARDS MO-153-AB-1 Figure 78. 14-Lead Plastic Thin Shrink Small Outline Package (TSSOP) RU-14 ORDERING GUIDE Model AD8343ARU AD8343ARU-REEL AD8343ARU-REEL7 AD8343ARUZ1 AD8343ARUZ-REEL1 AD8343ARUZ-REEL71 AD8343-EVAL AD8343-EVALZ1 1 Temperature Range –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C –40°C to +85°C Package Description 14-Lead Plastic TSSOP 14-Lead Plastic TSSOP, 13" Tape and Reel 14-Lead Plastic TSSOP, 7" Tape and Reel 14-Lead Plastic TSSOP 14-Lead Plastic TSSOP, 13" Tape and Reel 14-Lead Plastic TSSOP, 7" Tape and Reel Evaluation Board Evaluation Board Z = Pb-free part. ©2006 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. C01034-0-11/06(B) Rev. B | Page 32 of 32 Package Option RU-14 RU-14 RU-14 RU-14 RU-14 RU-14