50 MHz to 2 GHz Quadrature Demodulator ADL5387 Operating RF frequency 50 MHz to 2 GHz LO input at 2 × fLO 100 MHz to 4 GHz Input IP3: 31 dBm @ 900 MHz Input IP2: 62 dBm @ 900 MHz Input P1dB: 13 dBm @ 900 MHz Noise figure (NF) 12.0 dB @ 140 MHz 14.7 dB @ 900 MHz Voltage conversion gain > 4 dB Quadrature demodulation accuracy Phase accuracy ~0.4° Amplitude balance ~0.05 dB Demodulation bandwidth ~240 MHz Baseband I/Q drive 2 V p-p into 200 Ω Single 5 V supply FUNCTIONAL BLOCK DIAGRAM 24 23 22 21 20 19 1 CMRF CMRF RFIP RFIN CMRF VPX VPA VPB 18 2 COM 3 BIAS 4 VPL 5 VPL 6 VPL CML 7 VPB 17 QHI 16 DIVIDE-BY-2 PHASE SPLITTER QLO 15 IHI 14 ILO 13 LOIP LOIN CML 8 9 10 CML COM 11 12 06764-001 FEATURES Figure 1. APPLICATIONS QAM/QPSK RF/IF demodulators W-CDMA/CDMA/CDMA2000/GSM Microwave point-to-(multi)point radios Broadband wireless and WiMAX Broadband CATVs GENERAL DESCRIPTION The ADL5387 is a broadband quadrature I/Q demodulator that covers an RF/IF input frequency range from 50 MHz to 2 GHz. With a NF = 13.2 dB, IP1dB = 12.7 dBm, and IIP3 = 32 dBm @ 450 MHz, the ADL5387 demodulator offers outstanding dynamic range suitable for the demanding infrastructure direct-conversion requirements. The differential RF/IF inputs provide a wellbehaved broadband input impedance of 50 Ω and are best driven from a 1:1 balun for optimum performance. The fully balanced design minimizes effects from second-order distortion. The leakage from the LO port to the RF port is <−70 dBc. Differential dc-offsets at the I and Q outputs are <10 mV. Both of these factors contribute to the excellent IIP2 specifications > 60 dBm. Ultrabroadband operation is achieved with a divide-by-2 method for local oscillator (LO) quadrature generation. Over a wide range of LO levels, excellent demodulation accuracy is achieved with amplitude and phase balances ~0.05 dB and ~0.4°, respectively. The demodulated in-phase (I) and quadrature (Q) differential outputs are fully buffered and provide a voltage conversion gain of >4 dB. The buffered baseband outputs are capable of driving a 2 V p-p differential signal into 200 Ω. The ADL5387 is fabricated using the Analog Devices, Inc. advanced silicon-germanium bipolar process and is available in a 24-lead exposed paddle LFCSP. The ADL5387 operates off a single 4.75 V to 5.25 V supply. The supply current is adjustable with an external resistor from the BIAS pin to ground. Rev. 0 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 ©2007 Analog Devices, Inc. All rights reserved. ADL5387 TABLE OF CONTENTS Features .............................................................................................. 1 Mixers .......................................................................................... 14 Applications....................................................................................... 1 Emitter Follower Buffers ........................................................... 14 Functional Block Diagram .............................................................. 1 Bias Circuit.................................................................................. 14 General Description ......................................................................... 1 Applications..................................................................................... 15 Revision History ............................................................................... 2 Basic Connections...................................................................... 15 Specifications..................................................................................... 3 Power Supply............................................................................... 15 Absolute Maximum Ratings............................................................ 5 Local Oscillator (LO) Input ...................................................... 15 ESD Caution.................................................................................. 5 RF Input....................................................................................... 16 Pin Configuration and Function Descriptions............................. 6 Baseband Outputs ...................................................................... 16 Typical Performance Characteristics ............................................. 7 Error Vector Magnitude (EVM) Performance ....................... 17 Distributions for fRF = 140 MHz ............................................... 10 Low IF Image Rejection............................................................. 18 Distributions for fRF = 450 MHz ............................................... 11 Example Baseband Interface..................................................... 18 Distributions for fRF = 900 MHz ............................................... 12 Characterization Setups................................................................. 21 Distributions for fRF = 1900 MHz............................................. 13 Evaluation Board ............................................................................ 23 Circuit Description......................................................................... 14 Outline Dimensions ....................................................................... 26 LO Interface................................................................................. 14 Ordering Guide .......................................................................... 26 V-to-I Converter......................................................................... 14 REVISION HISTORY 10/07—Revision 0: Initial Version Rev. 0 | Page 2 of 28 ADL5387 SPECIFICATIONS VS = 5 V, TA = 25°C, fRF = 900 MHz, fIF = 4.5 MHz, PLO = 0 dBm, BIAS pin open, ZO = 50 Ω, unless otherwise noted, baseband outputs differentially loaded with 450 Ω. Table 1. Parameter OPERATING CONDITIONS LO Frequency Range RF Frequency Range LO INPUT Input Return Loss LO Input Level I/Q BASEBAND OUTPUTS Voltage Conversion Gain Demodulation Bandwidth Quadrature Phase Error I/Q Amplitude Imbalance Output DC Offset (Differential) Output Common-Mode 0.1 dB Gain Flatness Output Swing Peak Output Current POWER SUPPLIES Voltage Current DYNAMIC PERFORMANCE @ RF = 140 MHz Conversion Gain Input P1dB (IP1dB) Second-Order Input Intercept (IIP2) Third-Order Input Intercept (IIP3) LO to RF RF to LO I/Q Magnitude Imbalance I/Q Phase Imbalance LO to I/Q Noise Figure Noise Figure under Blocking Conditions Condition Min External input = 2xLO frequency 0.1 0.05 Typ Max Unit 4 2 GHz GHz LOIP, LOIN −10 AC-coupled into LOIP with LOIN bypassed, measured at 2 GHz −6 QHI, QLO, IHI, ILO 450 Ω differential load on I and Q outputs (@ 900 MHz) 200 Ω differential load on I and Q outputs (@ 900 MHz) 1 V p-p signal 3 dB bandwidth @ 900 MHz 0 dBm LO input Differential 200 Ω load Each pin VPA, VPL, VPB, VPX 0 −5 dBm each input tone −5 dBm each input tone RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the RF port LOIN, LOIP terminated in 50 Ω RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the BB port With a −5 dBm interferer 5 MHz away Rev. 0 | Page 3 of 28 +6 dBm 4.3 dB 3.2 dB 240 0.4 0.1 ±5 VPOS − 2.8 40 2 12 MHz Degrees dB mV V MHz V p-p mA 4.75 BIAS pin open RBIAS = 4 kΩ RFIP, RFIN dB 180 157 5.25 V mA mA 4.7 13 67 31 −100 dB dBm dBm dBm dBm −95 0.05 0.2 −39 dBc dB Degrees dBm 12.0 14.4 dB dB ADL5387 Parameter DYNAMIC PERFORMANCE @ RF = 450 MHz Conversion Gain Input P1dB (IP1dB) Second-Order Input Intercept (IIP2) Third-Order Input Intercept (IIP3) LO to RF RF to LO I/Q Magnitude Imbalance I/Q Phase Imbalance LO to I/Q Noise Figure DYNAMIC PERFORMANCE @ RF = 900 MHz Conversion Gain Input P1dB (IP1dB) Second-Order Input Intercept (IIP2) Third-Order Input Intercept (IIP3) LO to RF RF to LO I/Q Magnitude Imbalance I/Q Phase Imbalance LO to I/Q Noise Figure Noise Figure under Blocking Conditions DYNAMIC PERFORMANCE @ RF = 1900 MHz Conversion Gain Input P1dB (IP1dB) Second-Order Input Intercept (IIP2) Third-Order Input Intercept (IIP3) LO to RF RF to LO I/Q Magnitude Imbalance I/Q Phase Imbalance LO to I/Q Noise Figure Noise Figure under Blocking Conditions Condition Min −5 dBm each input tone −5 dBm each input tone RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the RF port LOIN, LOIP terminated in 50 Ω RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the BB port −5 dBm each input tone −5 dBm each input tone RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the RF port LOIN, LOIP terminated in 50 Ω RFIN, RFIP terminated in 50 Ω, 1XLO appearing at the BB port With a −5 dBm interferer 5 MHz away −5 dBm each input tone −5 dBm each input tone RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the RF port LOIN, LOIP terminated in 50 Ω RFIN, RFIP terminated in 50 Ω, 1xLO appearing at the BB port With a −5 dBm interferer 5 MHz away Rev. 0 | Page 4 of 28 Typ Max Unit 4.4 12.7 69.2 32.8 −87 dB dBm dBm dBm dBm −90 0.05 0.6 −38 dBc dB Degrees dBm 13.2 dB 4.3 12.8 61.7 31.2 −79 dB dBm dBm dBm dBm −88 0.05 0.2 −41 dBc dB Degrees dBm 14.7 15.8 dB dB 3.8 12.8 59.8 27.4 −75 dB dBm dBm dBm dBm −70 0.05 0.3 −43 dBc dB Degrees dBm 16.5 18.7 dB dB ADL5387 ABSOLUTE MAXIMUM RATINGS ESD CAUTION Table 2. Parameter Supply Voltage VPOS1, VPOS2, VPOS3 LO Input Power RF/IF Input Power Internal Maximum Power Dissipation θJA Maximum Junction Temperature Operating Temperature Range Storage Temperature Range Rating 5.5 V 13 dBm (re: 50 Ω) 15 dBm (re: 50 Ω) 1100 mW 54°C/W 150°C −40°C to +85°C −65°C to +125°C Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only; functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Rev. 0 | Page 5 of 28 ADL5387 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS 23 22 21 20 19 1 2 COM 3 BIAS 4 VPL 5 VPL 6 VPL CML 7 VPB 17 QHI 16 ADL5387 TOP VIEW (Not to Scale) QLO 15 IHI 14 ILO 13 LOIP LOIN CML 8 9 10 CML COM 11 12 06764-002 24 CMRF CMRF RFIP RFIN CMRF VPX VPA VPB 18 Figure 2. Pin Configuration Table 3. Pin Function Descriptions Pin No. 1, 4 to 6, 17 to 19 2, 7, 10 to 12, 20, 23, 24 3 Mnemonic VPA, VPL, VPB, VPX BIAS 8, 9 LOIP, LOIN 13 to 16 ILO, IHI, QLO, QHI 21, 22 RFIN, RFIP COM, CML, CMRF EP Description Supply. Positive supply for LO, IF, biasing and baseband sections, respectively. These pins should be decoupled to board ground using appropriate sized capacitors. Ground. Connect to a low impedance ground plane. Bias Control. A resistor can be connected between BIAS and COM to reduce the mixer core current. The default setting for this pin is open. Local Oscillator. External LO input is at 2xLO frequency. A single-ended LO at 0 dBm can be applied through a 1000 pF capacitor to LOIP. LOIN should be ac-grounded, also using a 1000 pF. These inputs can also be driven differentially through a balun (recommended balun is M/A-COM ETC1-1-13). I-Channel and Q-Channel Mixer Baseband Outputs. These outputs have a 50 Ω differential output impedance (25 Ω per pin). The bias level on these pins is equal to VPOS − 2.8 V. Each output pair can swing 2 V p-p (differential) into a load of 200 Ω. Output 3 dB bandwidth is 240 MHz. RF Input. A single-ended 50 Ω signal can be applied to the RF inputs through a 1:1 balun (recommended balun is M/A-COM ETC1-1-13). Ground-referenced inductors must also be connected to RFIP and RFIN (recommended values = 120 nH). Exposed Paddle. Connect to a low impedance ground plane Rev. 0 | Page 6 of 28 ADL5387 TYPICAL PERFORMANCE CHARACTERISTICS VS = 5 V, TA = 25°C, LO drive level = 0 dBm, RBIAS = open, unless otherwise noted. 5 TA = –40°C TA = +25°C TA = +85°C NORMALIZED TO 1MHz 0 INPUT P1dB 15 BB RESPONSE (dB) GAIN (dB), IP1dB (dBm) 20 10 GAIN 5 –5 –10 –15 –20 400 600 800 1000 1200 1400 1600 1800 2000 RF FREQUENCY (MHz) –30 I CHANNEL Q CHANNEL 70 19 NOISE FIGURE (dB) IIP2, IIP3 (dBm) 50 40 30 0 200 400 600 800 1000 1200 1400 1600 1800 2000 RF FREQUENCY (MHz) 13 11 7 06764-004 10 15 9 INPUT IP3 (I AND Q CHANNELS) 20 0 200 QUADRATURE PHASE ERROR (Degrees) 0.5 0 –0.5 –1.0 –1.5 0 200 400 600 800 1000 1200 1400 1600 1800 2000 RF FREQUENCY (MHz) 06764-005 MAGNITUDE ERROR (dB) 4 1.0 –2.0 600 800 1000 1200 1400 1600 1800 2000 Figure 7. Noise Figure vs. RF Frequency TA = –40°C TA = +25°C TA = +85°C 1.5 400 RF FREQUENCY (MHz) Figure 4. Input Third-Order Intercept (IIP3) and Input Second-Order Intercept Point (IIP2) vs. RF Frequency 2.0 1000 TA = –40°C TA = +25°C TA = +85°C 17 INPUT IP2 100 Figure 6. Normalized I/Q Baseband Frequency Response TA = +85°C TA = +25°C TA = –40°C 60 10 BB FREQUENCY (MHz) Figure 3. Conversion Gain and Input 1 dB Compression Point (IP1dB) vs. RF Frequency 80 1 06764-007 200 Figure 5. I/Q Gain Mismatch vs. RF Frequency TA = –40°C TA = +25°C TA = +85°C 3 2 1 0 –1 –2 –3 –4 0 200 400 600 800 1000 1200 1400 1600 1800 2000 RF FREQUENCY (MHz) Figure 8. I/Q Quadrature Phase Error vs. RF Frequency Rev. 0 | Page 7 of 28 06764-008 0 06764-003 0 06764-006 –25 NOISE FIGURE GAIN 5 35 INPUT IP3 0 –6 –5 –4 –3 –2 –1 0 1 2 3 4 5 6 20 LO LEVEL (dBm) 15 GAIN INPUT IP3 0 –6 16 165 155 NOISE FIGURE 12 8 145 1 135 100 10 RBIAS (kΩ) RBIAS = 10kΩ 15 RBIAS = 4kΩ RBIAS = 1.4kΩ 5 –25 –20 –15 –10 –5 0 5 RF BLOCKER INPUT POWER (dBm) Figure 11. Noise Figure vs. Input Blocker Level, fRF = 900 MHz (RF Blocker 5 MHz Offset) 06764-011 NOISE FIGURE (dB) 20 0 –30 –2 –1 0 1 2 3 4 5 6 20 INPUT IP3 24 20 NOISE FIGURE 16 12 8 1 10 100 100 RBIAS (kΩ) Figure 13. IIP3 and Noise Figure vs. RBIAS, fRF = 900 MHz GAIN (dB), IP1dB, IIP2, I AND Q CHANNELS (dBm) 25 10 –3 TA = –40°C TA = +25°C TA = +85°C 28 Figure 10. Noise Figure, IIP3, and Supply Current vs. RBIAS, fRF = 140 MHz RBIAS = 100kΩ –4 LO LEVEL (dBm) IIP3 (dBm) AND NOISE FIGURE (dB) SUPPLY CURRENT 20 –5 32 SUPPLY CURRENT (mA) 175 35 Figure 12. Conversion Gain, Noise Figure, IIP3, IIP2, and IP1dB vs. LO Level, fRF = 900 MHz 185 INPUT IP3 24 50 5 06764-010 IIP3 (dBm) AND NOISE FIGURE (dB) 28 INPUT P1dB INPUT IP2, Q CHANNEL 195 TA = –40°C TA = +25°C TA = +85°C 65 10 Figure 9. Conversion Gain, Noise Figure, IIP3, IIP2, and IP1dB vs. LO Level, fRF = 140 MHz 32 NOISE FIGURE INPUT IP2, INPUT IP3 (dBm) 50 INPUT IP2, I CHANNEL 06764-013 INPUT P1dB 10 80 06764-014 65 INPUT IP2, I CHANNEL INPUT IP2, INPUT IP3 (dBm) 15 20 06764-012 80 INPUT IP2, Q CHANNEL GAIN (dB), INPUT P1dB (dBm), NOISE FIGURE (dB) 20 06764-009 GAIN (dB), INPUT P1dB (dBm), NOISE FIGURE (dB) ADL5387 80 70 60 140MHz: GAIN 140MHz: IP1dB 50 140MHz: IIP2, I CHANNEL 140MHz: IIP2, Q CHANNEL 40 450MHz: GAIN 450MHz: IP1dB 30 450MHz: IIP2, I CHANNEL 450MHz: IIP2, Q CHANNEL 20 10 0 1 10 RBIAS (kΩ) Figure 14. Conversion Gain, IP1dB, IIP2 I Channel, and IIP2 Q Channel vs. RBIAS Rev. 0 | Page 8 of 28 ADL5387 80 75 INPUT IP2, I CHANNEL 25 70 20 65 INPUT IP2, Q CHANNEL 15 60 10 55 0 5 10 IP1dB –40 –50 –60 1xLO –70 –80 –90 2xLO 15 20 25 30 35 40 45 50 50 –100 BB FREQUENCY (MHz) 0 200 400 600 800 1000 1200 1400 1600 1800 2000 INTERNAL 1xLO FREQUENCY (MHz) Figure 15. IIIP3, IIP2, IP1dB vs. Baseband Frequency 06764-018 5 TA = –40°C TA = +25°C TA = +85°C –30 LO LEAKAGE (dBm) IIP3 06764-015 IP1dB, IIP3 (dBm) 30 –20 INPUT IP2, I AND Q CHANNELS (dBm) 35 Figure 18. LO-to-RF Leakage vs. Internal 1xLO Frequency 0 –20 –10 LEAKAGE (dBc) FEEDTHROUGH (dBm) –40 –20 –30 1xLO (INTERNAL) –40 –50 –60 –80 2xLO (EXTERNAL) –60 –100 0 200 400 600 800 1000 1200 1400 1600 1800 2000 INTERNAL 1xLO FREQUENCY (MHz) –120 06764-016 0 600 800 1000 1200 1400 1600 1800 2000 Figure 19. RF-to-LO Leakage vs. RF Frequency 0 0 –5 RETURN LOSS (dB) –5 RETURN LOSS (dB) 400 RF FREQUENCY (MHz) Figure 16. LO-to-BB Feedthrough vs. 1xLO Frequency (Internal LO Frequency) –10 –15 –20 –10 –15 –20 –25 0 200 400 600 800 1000 1200 1400 1600 1800 2000 RF FREQUENCY (MHz) 06764-017 –25 200 Figure 17. RF Port Return Loss vs. RF Frequency, Measured on Characterization Board through ETC1-1-13 Balun with 120 nH Bias Inductors Rev. 0 | Page 9 of 28 –30 0 500 1000 1500 2000 2500 3000 3500 FREQUENCY (MHz) Figure 20. Single-Ended LO Port Return Loss vs. LO Frequency, LOIN AC-Coupled to Ground 4000 06764-020 –80 06764-019 –70 ADL5387 DISTRIBUTIONS FOR fRF = 140 MHz 80 60 40 60 40 20 29 30 31 32 33 INPUT IP3 (dBm) 0 60 06764-021 100 TA = –40°C TA = +25°C TA = +85°C 80 60 40 20 11 12 13 14 15 INPUT P1dB (dBm) 60 40 0 10.5 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 80 60 40 12.0 12.5 13.0 13.5 TA = –40°C TA = +25°C TA = +85°C 60 40 20 20 0 –0.2 11.5 Figure 25. Noise Figure Distributions –0.1 0 0.1 I/Q GAIN MISMATCH (dB) 0.2 06764-023 PERCENTAGE (%) 80 11.0 NOISE FIGURE (dB) Figure 22. IP1dB Distributions 100 TA = –40°C TA = +25°C TA = +85°C 20 06764-022 0 10 75 Figure 24. IIP2 Distributions for I Channel and Q Channel PERCENTAGE (%) PERCENTAGE (%) 80 70 INPUT IP2 (dBm) Figure 21. IIP3 Distributions 100 65 06764-025 0 28 I CHANNEL Q CHANNEL 06764-024 20 TA = –40°C TA = +25°C TA = +85°C 0 –1.0 –0.5 0 0.5 QUADRATURE PHASE ERROR (Degrees) Figure 26. I/Q Quadrature Error Distributions Figure 23. I/Q Gain Mismatch Distributions Rev. 0 | Page 10 of 28 1.0 06764-026 PERCENTAGE (%) 80 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 100 ADL5387 DISTRIBUTIONS FOR fRF = 450 MHz 80 60 40 60 40 20 31 32 33 34 35 INPUT IP3 (dBm) 0 60 06764-027 100 TA = –40°C TA = +25°C TA = +85°C 40 20 60 40 20 12 13 14 15 0 12.0 06764-028 11 INPUT P1dB (dBm) 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 80 60 40 13.5 14.0 14.5 15.0 TA = –40°C TA = +25°C TA = +85°C 60 40 20 20 0 –0.2 13.0 Figure 31. Noise Figure Distributions –0.1 0 0.1 I/Q GAIN MISMATCH (dB) 0.2 06764-029 PERCENTAGE (%) 80 12.5 NOISE FIGURE (dB) Figure 28. IP1dB Distributions 100 TA = –40°C TA = +25°C TA = +85°C 80 60 0 10 75 Figure 30. IIP2 Distributions for I Channel and Q Channel PERCENTAGE (%) PERCENTAGE (%) 80 70 INPUT IP2 (dBm) Figure 27. IIP3 Distributions 100 65 06764-031 0 30 I CHANNEL Q CHANNEL 06764-030 20 TA = –40°C TA = +25°C TA = +85°C 0 –1.0 –0.5 0 0.5 QUADRATURE PHASE ERROR (Degrees) Figure 32. I/Q Quadrature Error Distributions Figure 29. I/Q Gain Mismatch Distributions Rev. 0 | Page 11 of 28 1.0 06764-032 PERCENTAGE (%) 80 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 100 ADL5387 DISTRIBUTIONS FOR fRF = 900 MHz 80 60 40 60 40 20 31 32 33 34 35 INPUT IP3 (dBm) 0 55 06764-033 100 TA = –40°C TA = +25°C TA = +85°C 80 60 40 20 11 12 13 14 15 INPUT P1dB (dBm) 40 0 13.0 14.0 14.5 15.0 15.5 16.0 Figure 37. Noise Figure Distributions 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 80 60 40 TA = –40°C TA = +25°C TA = +85°C 60 40 20 20 0 –0.2 13.5 NOISE FIGURE (dB) –0.1 0 0.1 I/Q GAIN MISMATCH (dB) 0.2 06764-035 PERCENTAGE (%) 80 TA = –40°C TA = +25°C TA = +85°C 60 Figure 34. IP1dB Distributions 100 75 20 06764-034 0 10 70 Figure 36. IIP2 Distributions for I Channel and Q Channel PERCENTAGE (%) PERCENTAGE (%) 80 65 INPUT IP2 (dBm) Figure 33. IIP3 Distributions 100 60 06764-037 0 30 I CHANNEL Q CHANNEL 06764-036 20 TA = –40°C TA = +25°C TA = +85°C 0 –1.0 –0.5 0 0.5 QUADRATURE PHASE ERROR (Degrees) Figure 38. I/Q Quadrature Error Distributions Figure 35. I/Q Gain Mismatch Distributions Rev. 0 | Page 12 of 28 1.0 06764-038 PERCENTAGE (%) 80 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 100 ADL5387 DISTRIBUTIONS FOR fRF = 1900 MHz PERCENTAGE (%) 80 100 TA = –40°C TA = +25°C TA = +85°C 80 PERCENTAGE (%) 100 60 40 20 60 40 TA = –40°C TA = +25°C TA = +85°C 20 27 28 29 30 31 INPUT IP3 (dBm) 0 52 06764-039 100 TA = –40°C TA = +25°C TA = +85°C 40 12 13 14 15 68 40 0 15.0 06764-040 11 15.5 16.0 16.5 17.0 17.5 18.0 NOISE FIGURE (dB) Figure 43. Noise Figure Distributions 100 TA = –40°C TA = +25°C TA = +85°C PERCENTAGE (%) 80 60 40 TA = –40°C TA = +25°C TA = +85°C 60 40 20 20 –0.1 0 0.1 I/Q GAIN MISMATCH (dB) 0.2 06764-041 PERCENTAGE (%) 66 60 Figure 40. IP1dB Distributions 0 –0.2 64 20 INPUT P1dB (dBm) 80 62 06764-043 20 100 60 TA = –40°C TA = +25°C TA = +85°C 80 60 0 10 58 Figure 42. IIP2 Distributions for I Channel and Q Channel PERCENTAGE (%) PERCENTAGE (%) 80 56 INPUT IP2 (dBm) Figure 39. IIP3 Distributions 100 54 0 –1.0 –0.5 0 0.5 QUADRATURE PHASE ERROR (Degrees) Figure 44. I/Q Quadrature Error Distributions Figure 41. I/Q Gain Mismatch Distributions Rev. 0 | Page 13 of 28 1.0 06764-044 0 26 06764-042 I CHANNEL Q CHANNEL ADL5387 CIRCUIT DESCRIPTION The ADL5387 can be divided into five sections: the local oscillator (LO) interface, the RF voltage-to-current (V-to-I) converter, the mixers, the differential emitter follower outputs, and the bias circuit. A detailed block diagram of the device is shown in Figure 45. BIAS The ADL5387 has two double-balanced mixers: one for the in-phase channel (I channel) and one for the quadrature channel (Q channel). These mixers are based on the Gilbert cell design of four cross-connected transistors. The output currents from the two mixers are summed together in the resistive loads that then feed into the subsequent emitter follower buffers. ILO LOIP RFIN The differential RF input signal is applied to a resistively degenerated common base stage, which converts the differential input voltage to output currents. The output currents then modulate the two half-frequency LO carriers in the mixer stage. MIXERS IHI RFIP V-TO-I CONVERTER DIVIDE-BY-TWO QUADRATURE PHASE SPLITTER EMITTER FOLLOWER BUFFERS The output emitter followers drive the differential I and Q signals off-chip. The output impedance is set by on-chip 25 Ω series resistors that yield a 50 Ω differential output impedance for each baseband port. The fixed output impedance forms a voltage divider with the load impedance that reduces the effective gain. For example, a 500 Ω differential load has 1 dB lower effective gain than a high (10 kΩ) differential load impedance. LOIN QLO 06764-045 QHI Figure 45. Block Diagram The LO interface generates two LO signals at 90° of phase difference to drive two mixers in quadrature. RF signals are converted into currents by the V-to-I converters that feed into the two mixers. The differential I and Q outputs of the mixers are buffered via emitter followers. Reference currents to each section are generated by the bias circuit. A detailed description of each section follows. LO INTERFACE The LO interface consists of a buffer amplifier followed by a frequency divider that generate two carriers at half the input frequency and in quadrature with each other. Each carrier is then amplified and amplitude-limited to drive the doublebalanced mixers. BIAS CIRCUIT A band gap reference circuit generates the proportional-toabsolute temperature (PTAT) as well as temperature-independent reference currents used by different sections. The mixer current can be reduced via an external resistor between the BIAS pin and ground. When the BIAS pin is open, the mixer runs at maximum current and hence the greatest dynamic range. The mixer current can be reduced by placing a resistance to ground; therefore, reducing overall power consumption, noise figure, and IIP3. The effect on each of these parameters is shown in Figure 10, Figure 13, and Figure 14. Rev. 0 | Page 14 of 28 ADL5387 APPLICATIONS INFORMATION BASIC CONNECTIONS LO INPUT 8 LOIP 9 LOIN POWER SUPPLY 06764-047 1000pF Figure 47 shows the basic connections schematic for the ADL5387. 1000pF The nominal voltage supply for the ADL5387 is 5 V and is applied to the VPA, VPB, VPL, and VPX pins. Ground should be connected to the COM, CML, and CMRF pins. Each of the supply pins should be decoupled using two capacitors; recommended capacitor values are 100 pF and 0.1 μF. Figure 46. Single-Ended LO Drive The recommended LO drive level is between −6 dBm and +6 dBm. The LO frequency at the input to the device should be twice that of the desired LO frequency at the mixer core. The applied LO frequency range is between 100 MHz and 4 GHz. LOCAL OSCILLATOR (LO) INPUT The LO port is driven in a single-ended manner. The LO signal must be ac-coupled via a 1000 pF capacitor directly into LOIP, and LOIN is ac-coupled to ground also using a 1000 pF capacitor. The LO port is designed for a broadband 50 Ω match and therefore exhibits excellent return loss from 100 MHz to 4 GHz. The LO return loss can be seen in Figure 20. Figure 46 shows the LO input configuration. ETC1-1-13 RFC 120nH 24 23 22 21 20 19 CMRF CMRF RFIP RFIN CMRF VPX VPOS 1 VPA VPB 17 3 BIAS QHI 16 ADL5387 4 VPL QHI QLO 15 5 VPL IHI 14 6 VPL ILO 13 LOIP LOIN CML CML COM 100pF CML 0.1µF 0.1µF 100pF 2 COM VPOS VPOS VPB 18 100pF 7 8 9 10 11 12 QLO IHI ILO 1000pF 1000pF LO Figure 47. Basic Connections Schematic for ADL5387 Rev. 0 | Page 15 of 28 06764-046 0.1µF 120nH 1000pF 1000pF ADL5387 120nH 21 RFIN 1000pF ETC1-1-13 1000pF 22 RFIP RF INPUT 06764-048 120nH –10 –12 –14 –16 –18 –20 –22 –24 –28 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 FREQUENCY (GHz) 1.8 2.0 06764-049 –26 Figure 49. Differential RF Port Return Loss BASEBAND OUTPUTS The baseband outputs QHI, QLO, IHI, and ILO are fixed impedance ports. Each baseband pair has a 50 Ω differential output impedance. The outputs can be presented with differential loads as low as 200 Ω (with some degradation in linearity and gain) or high impedance differential loads (500 Ω or greater impedance yields the same excellent linearity) that is typical of an ADC. The TCM9-1 9:1 balun converts the differential IF output to single-ended. When loaded with 50 Ω, this balun presents a 450 Ω load to the device. The typical maximum linear voltage swing for these outputs is 2 V p-p differential. The bias level on these pins is equal to VPOS − 2.8 V. The output 3 dB bandwidth is 240 MHz. Figure 50 shows the baseband output configuration. Figure 48. RF Input QHI 16 QHI QLO 15 QLO IHI 14 IHI ILO 13 ILO 06764-050 The RF inputs have a differential input impedance of approximately 50 Ω. For optimum performance, the RF port should be driven differentially through a balun. The recommended balun is M/A-COM ETC1-1-13. The RF inputs to the device should be ac-coupled with 1000 pF capacitors. Ground-referenced choke inductors must also be connected to RFIP and RFIN (recommended value = 120 nH, Coilcraft 0402CS-R12XJL) for appropriate biasing. Several important aspects must be taken into account when selecting an appropriate choke inductor for this application. First, the inductor must be able to handle the approximately 40 mA of standing dc current being delivered from each of the RF input pins (RFIP, RFIN). (The suggested 0402 inductor has a 50 mA current rating). The purpose of the choke inductors is to provide a very low resistance dc path to ground and high ac impedance at the RF frequency so as not to affect the RF input impedance. A choke inductor that has a selfresonant frequency greater than the RF input frequency ensures that the choke is still looking inductive and therefore has a more predictable ac impedance (jωL) at the RF frequency. Figure 48 shows the RF input configuration. The differential RF port return loss has been characterized as shown in Figure 49. S(1, 1) (dB) RF INPUT Figure 50. Baseband Output Configuration Rev. 0 | Page 16 of 28 ADL5387 Figure 52 shows the EVM performance of the ADL5387 when ac-coupled, with an IEEE 802.16e WiMAX signal. The ADL5387 shows excellent EVM performance for various modulation schemes. Figure 51 shows typical EVM performance over input power range for a point-to-point application with 16 QAM modulation schemes and zero-IF baseband. The differential dc offsets on the ADL5387 are in the order of a few mV. However, ac coupling the baseband outputs with 10 μF capacitors helps to eliminate dc offsets and enhances EVM performance. With a 10 MHz BW signal, 10 μF ac coupling capacitors with the 500 Ω differential load results in a high-pass corner frequency of ~64 Hz which absorbs an insignificant amount of modulated signal energy from the baseband signal. By using ac coupling capacitors at the baseband outputs, the dc offset effects, which can limit dynamic range at low input power levels, can be eliminated. 0 –5 –10 –15 –25 –30 –35 –40 –45 –50 –50 –30 –20 –10 0 10 20 Figure 52. RF = 750MHz MHz, IF = 0 Hz, EVM vs. Input Power for a 16 QAM 10 MHz Bandwidth Mobile WiMAX Signal (AC-Coupled Baseband Outputs) Figure 53 exhibits the zero IF EVM performance of a WCDMA signal over a wide RF input power range. 0 –5 0 –10 –15 EVM (dB) –10 –15 –20 –20 –25 –30 –25 –35 –40 –40 –45 –70 –60 –50 –40 –30 –20 INPUT POWER (dBm) –60 –50 –40 –30 –20 INPUT POWER (dBm) –10 0 10 06764-051 –45 –10 0 10 06764-053 –35 –30 –50 –70 –40 INPUT POWER (dBm) –5 EVM (dB) –20 06764-052 EVM is a measure used to quantify the performance of a digital radio transmitter or receiver. A signal received by a receiver would have all constellation points at the ideal locations; however, various imperfections in the implementation (such as carrier leakage, phase noise, and quadrature error) cause the actual constellation points to deviate from the ideal locations. EVM (dB) ERROR VECTOR MAGNITUDE (EVM) PERFORMANCE Figure 53. RF = 1950 MHz, IF = 0 Hz, EVM vs. Input Power for a WCDMA (AC-Coupled Baseband Outputs) Figure 51. RF = 140 MHz, IF = 0 Hz, EVM vs. Input Power for a 16 QAM 10 Msym/s Signal (AC-Coupled Baseband Outputs) Rev. 0 | Page 17 of 28 ADL5387 COSωLOt 0° ωIF ωIF –ωIF 0 +ωIF –90° 0 +ωIF 0 +ωIF +90° ωLSB ωLO ωUSB 0° 0 +ωIF 06764-054 –ωIF SINωLOt Figure 54. Illustration of the Image Problem LOW IF IMAGE REJECTION EXAMPLE BASEBAND INTERFACE The image rejection ratio is the ratio of the intermediate frequency (IF) signal level produced by the desired input frequency to that produced by the image frequency. The image rejection ratio is expressed in decibels. Appropriate image rejection is critical because the image power can be much higher than that of the desired signal, thereby plaguing the down conversion process. Figure 54 illustrates the image problem. If the upper sideband (lower sideband) is the desired band, a 90° shift to the Q channel (I channel) cancels the image at the lower sideband (upper sideband). In most direct conversion receiver designs, it is desirable to select a wanted carrier within a specified band. The desired channel can be demodulated by tuning the LO to the appropriate carrier frequency. If the desired RF band contains multiple carriers of interest, the adjacent carriers would also be down converted to a lower IF frequency. These adjacent carriers can be problematic if they are large relative to the wanted carrier as they can overdrive the baseband signal detection circuitry. As a result, it is often necessary to insert a filter to provide sufficient rejection of the adjacent carriers. Figure 55 shows the excellent image rejection capabilities of the ADL5387 for low IF applications, such as CDMA2000. The ADL5387 exhibits image rejection greater than 45 dB over the broad frequency range for an IF = 1.23 MHz. It is necessary to consider the overall source and load impedance presented by the ADL5387 and ADC input to design the filter network. The differential baseband output impedance of the ADL5387 is 50 Ω. The ADL5387 is designed to drive a high impedance ADC input. It may be desirable to terminate the ADC input down to lower impedance by using a terminating resistor, such as 500 Ω. The terminating resistor helps to better define the input impedance at the ADC input. The order and type of filter network depends on the desired high frequency rejection required, pass-band ripple, and group delay. Filter design tables provide outlines for various filter types and orders, illustrating the normalized inductor and capacitor values for a 1 Hz cutoff frequency and 1 Ω load. After scaling the normalized prototype element values by the actual desired cut-off frequency and load impedance, the series reactance elements are halved to realize the final balanced filter network component values. –10 –20 –30 –40 –50 –60 –70 50 250 450 650 850 1050 1250 1450 1650 1850 RF INPUT FREQUENCY (MHz) 06764-055 IMAGE REJECTION AT 1.23MHz (dB) 0 Figure 55. Image Rejection vs. RF Input Frequency for a CDMA2000 Signal, IF = 1.23 MHz Rev. 0 | Page 18 of 28 ADL5387 The balanced configuration is realized as the 0.54 μH inductor is split in half to realize the network shown in Figure 56. LN = 0.074H NORMALIZED SINGLE-ENDED CONFIGURATION VS CN 14.814F RS = 0.1 RL RS = 50Ω 5 0 –5 –10 –15 RL= 500Ω –20 fC = 1Hz 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 FREQUENCY (MHz) 0.54µH DENORMALIZED SINGLE-ENDED EQUIVALENT VS 10 06764-157 RS = 50Ω Figure 57 and Figure 58 show the measured frequency response and group delay of the filter. MAGNITUDE RESPONSE (dB) As an example, a second-order, Butterworth, low-pass filter design is shown in Figure 56 where the differential load impedance is 500 Ω, and the source impedance of the ADL5387 is 50 Ω. The normalized series inductor value for the 10-to-1, load-tosource impedance ratio is 0.074 H, and the normalized shunt capacitor is 14.814 F. For a 10.9 MHz cutoff frequency, the single-ended equivalent circuit consists of a 0.54 μH series inductor followed by a 433 pF shunt capacitor. Figure 57. Baseband Filter Response 433pF 900 RL= 500Ω 800 0.27µH RL 2 = 250Ω RL = 250Ω 2 600 500 400 Figure 56. Second-Order, Butterworth, Low-Pass Filter Design Example 300 A complete design example is shown in Figure 59. A sixth-order Butterworth differential filter having a 1.9 MHz corner frequency interfaces the output of the ADL5387 to that of an ADC input. The 500 Ω load resistor defines the input impedance of the ADC. The filter adheres to typical direct conversion WCDMA applications, where 1.92 MHz away from the carrier IF frequency, 1 dB of rejection is desired and 2.7 MHz away 10 dB of rejection is desired. 200 Rev. 0 | Page 19 of 28 100 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 FREQUENCY (MHz) Figure 58. Baseband Filter Group Delay 1.8 06764-158 RS = 25Ω 2 433pF DELAY (ns) BALANCED CONFIGURATION VS 700 0.27µH 06764-056 RS = 25Ω 2 fC = 10.9MHz ADL5387 ETC1-1-13 120nH 20 19 RFIP RFIN CMRF VPX 1 VPA 100pF 100pF 2 COM 27µH 27µH 10µH 27µH 27µH 10µH QHI 16 ADL5387 4 VPL QLO 15 5 VPL IHI 14 6 VPL ILO 13 CML CML COM 8 9 10 11 12 1000pF CAC 10µF 1000pF 27µH 27µH 10µH 06764-159 LO 68pF LOIN 7 CAC 10µF 91pF LOIP 100pF CML 0.1µF 0.1µF VPB 17 3 BIAS VPOS CAC 10µF 270pF 0.1µF VPOS VPB 18 ADC INPUT 21 10µH ADC INPUT 22 27µH 500Ω 23 27µH 500Ω 24 CMRF VPOS CMRF CAC 10µF 68pF 1000pF 1000pF 91pF 120nH 270pF RFC Figure 59. Sixth Order Low-Pass Butterworth Baseband Filter Schematic Rev. 0 | Page 20 of 28 ADL5387 CHARACTERIZATION SETUPS 10 MHz. For the case where a blocker was applied, the output blocker was at 15 MHz baseband frequency. Note that great care must be taken when measuring NF in the presence of a blocker. The RF blocker generator must be filtered to prevent its noise (which increases with increasing generator output power) from swamping the noise contribution of the ADL5387. At least 30 dB of attention at the RF and image frequencies is desired. For example, with a 2xLO of 1848 MHz applied to the ADL5387, the internal 1xLO is 924 MHz. To obtain a 15 MHz output blocker signal, the RF blocker generator is set to 939 MHz and the filters tuned such that there is at least 30 dB of attenuation from the generator at both the desired RF frequency (934 MHz) and the image RF frequency (914 MHz). Finally, the blocker must be removed from the output (by the 10 MHz low-pass filter) to prevent the blocker from swamping the analyzer. Figure 60 to Figure 62 show the general characterization bench setups used extensively for the ADL5387. The setup shown in Figure 62 was used to do the bulk of the testing and used sinusoidal signals on both the LO and RF inputs. An automated AgilentVEE program was used to control the equipment over the IEEE bus. This setup was used to measure gain, IP1dB, IIP2, IIP3, I/Q gain match, and quadrature error. The ADL5387 characterization board had a 9-to-1 impedance transformer on each of the differential baseband ports to do the differential-to-singleended conversion. The two setups shown in Figure 60 and Figure 61 were used for making NF measurements. Figure 60 shows the setup for measuring NF with no blocker signal applied while Figure 61 was used to measure NF in the presence of a blocker. For both setups, the noise was measured at a baseband frequency of SNS RF ADL5387 VPOS CHAR BOARD I LO INPUT 6dB PAD HP 6235A POWER SUPPLY R1 50Ω AGILENT N8974A NOISE FIGURE ANALYZER LOW-PASS FILTER IEEE GND Q FROM SNS PORT CONTROL OUTPUT AGILENT 8665B SIGNAL GENERATOR PC CONTROLLER Figure 60. General Noise Figure Measurement Setup Rev. 0 | Page 21 of 28 06764-057 IEEE ADL5387 BAND-PASS TUNABLE FILTER BAND-REJECT TUNABLE FILTER 6dB PAD R&S SMT03 SIGNAL GENERATOR RF GND ADL5387 6dB PAD VPOS CHAR BOARD LOW-PASS FILTER I LO 6dB PAD HP 6235A POWER SUPPLY R&S FSEA30 SPECTRUM ANALYZER R1 50Ω Q HP87405 LOW NOISE PREAMP 06764-058 BAND-PASS CAVITY FILTER AGILENT 8665B SIGNAL GENERATOR Figure 61. Measurement Setup for Noise Figure in the Presence of a Blocker 3dB PAD RF AMPLIFIER 3dB PAD IN RF OUT 3dB PAD IEEE VP GND 3dB PAD AGILENT 11636A R&S SMT-06 6dB PAD IEEE RF SWITCH MATRIX VPOS CHAR BOARD LO I 6dB PAD IEEE 6dB PAD AGILENT E3631 PWER SUPPLY RF INPUT AGILENT E8257D SIGNAL GENERATOR IEEE PC CONTROLLER IEEE R&S FSEA30 SPECTRUM ANALYZER Figure 62. General ADL5387 Characterization Setup Rev. 0 | Page 22 of 28 HP 8508A VECTOR VOLTMETER 06764-059 IEEE Q 6dB PAD ADL5387 IEEE RF GND INPUT CHANNELS A AND B R&S SMT-06 ADL5387 EVALUATION BOARD The ADL5387 evaluation board is available. The board can be used for single-ended or differential baseband analysis. The default configuration of the board is for single-ended baseband analysis. T1 RFC C1 23 22 21 20 19 CMRF RFIP RFIN CMRF VPX R7 R6 VPB 18 VPOS C8 C2 2 COM VPB 17 3 BIAS QHI 16 ADL5387 4 VPL C9 R9 Q OUTPUT OR QHI R14 R15 QLO 15 T2 C12 R3 5 VPL IHI 14 6 VPL ILO 13 R16 LOIP LOIN CML CML COM C4 CML 7 8 9 10 11 12 QLO R10 R11 R4 C5 I OUTPUT OR IHI R5 T3 C13 R13 C6 R17 C7 ILO R12 T4 06764-060 C3 L1 24 1 VPA R2 VPOS C10 CMRF VPOS R1 C11 L2 R8 LO Figure 63. Evaluation Board Schematic Rev. 0 | Page 23 of 28 ADL5387 Table 4. Evaluation Board Configuration Options Component VPOS, GND R1, R3, R6 C1, C2, C3, C4, C8, C9 C5, C6, C7, C10, C11 R4, R5, R9 to R16 L1, L2, R7, R8 T2, T3 C12, C13 R17 T1 R2 Function Power Supply and Ground Vector Pins. Power Supply Decoupling. Shorts or power supply decoupling resistors. The capacitors provide the required dc coupling up to 2 GHz. AC Coupling Capacitors. These capacitors provide the required ac coupling from 50 MHz to 2 GHz. Single-Ended Baseband Output Path. This is the default configuration of the evaluation board. R14 to R16 and R4, R5, and R13 are populated for appropriate balun interface. R9, R10 and R11, R12 are not populated. Baseband outputs are taken from QHI and IHI. The user can reconfigure the board to use full differential baseband outputs. R9 to R12 provide a means to bypass the 9:1 TCM9-1 transformer to allow for differential baseband outputs. Access the differential baseband signals by populating R9 to R12 with 0 Ω and not populating R4, R5, R13 to R16. This way the transformer does not need to be removed. The baseband outputs are taken from the SMAs of Q_HI, Q_LO, I_HI, and I_LO. Input Biasing. Inductance and resistance sets the input biasing of the common base input stage. Default value is 120 nH. IF Output Interface. TCM9-1 converts a differential high impedance IF output to a singleended output. When loaded with 50 Ω, this balun presents a 450 Ω load to the device. The center tap can be decoupled through a capacitor to ground. Decoupling Capacitors. C12 and C13 are the decoupling capacitors used to reject noise on the center tap of the TCM9-1. LO Input Interface. The LO is driven as a single-ended signal. Although, there is no performance change for a differential signal drive, the option is available by placing a transformer (T4, ETC1-1-13) on the LO input path. RF Input Interface. ETC1-1-13 is a 1:1 RF balun that converts the single-ended RF input to differential signal. RBIAS. Optional bias setting resistor. See the Bias Circuit section to see how to use this feature. Rev. 0 | Page 24 of 28 Default Condition Not Applicable R1, R3, R6 = 0 Ω (0805) C2, C4, C8 = 100 pF (0402) C1, C3, C9 = 0.1 μF (0603) C5, C6, C10, C11 = 1000 pF (0402), C7 = Open R4, R5, R13 to R16 = 0 Ω (0402), R9 to R12 = Open L1, L2 = 120 nH (0402) R7, R8 = 0 Ω (0402) T2, T3 = TCM9-1, 9:1 (Mini-Circuits) C12, C13 = 0.1 μF (0402) R17 = 0 Ω (0402) T1 = ETC1-1-13, 1:1 (M/A COM) R2 = Open 06764-166 06764-164 ADL5387 Figure 66. Evaluation Board Bottom Layer 06764-165 06764-167 Figure 64. Evaluation Board Top Layer Figure 67. Evaluation Board Bottom Layer Silkscreen Figure 65. Evaluation Board Top Layer Silkscreen Rev. 0 | Page 25 of 28 ADL5387 OUTLINE DIMENSIONS 0.60 MAX 4.00 BSC SQ PIN 1 INDICATOR 0.60 MAX TOP VIEW 0.50 BSC 3.75 BSC SQ 0.50 0.40 0.30 1.00 0.85 0.80 12° MAX SEATING PLANE 0.80 MAX 0.65 TYP 0.30 0.23 0.18 PIN 1 INDICATOR 19 18 24 1 *2.45 2.30 SQ 2.15 EXPOSED PAD (BOTTOMVIEW) 13 12 7 6 0.23 MIN 2.50 REF 0.05 MAX 0.02 NOM 0.20 REF COPLANARITY 0.08 *COMPLIANT TO JEDEC STANDARDS MO-220-VGGD-2 EXCEPT FOR EXPOSED PAD DIMENSION Figure 68. 24-Lead Lead Frame Chip Scale Package [LFCSP_VQ] 4 mm × 4 mm Body, Very Thin Quad (CP-24-2) Dimensions shown in millimeters ORDERING GUIDE Model ADL5387ACPZ-R7 1 ADL5387ACPZ-WP1 ADL5387-EVALZ1 1 Temperature Range –40°C to +85°C –40°C to +85°C Package Description 24-Lead LFCSP_VQ, 7” Tape and Reel 24-Lead LFCSP_VQ, Waffle Pack Evaluation Board Z = RoHS Compliant Part. Rev. 0 | Page 26 of 28 Package Option CP-24-2 CP-24-2 Ordering Quantity 1,500 64 ADL5387 NOTES Rev. 0 | Page 27 of 28 ADL5387 NOTES ©2007 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. D06764-0-10/07(0) Rev. 0 | Page 28 of 28