1 MHz to 8 GHz, 70 db Logarithmic Detector/Controller AD8318-EP

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1 Enhanced Product FEATURES Wide bandwidth: MHz to 8 GHz High accuracy: ±. db over db range (f <.8 GHz) Stability over temperature: ±. db Low noise measurement/controller output (VOUT) Pulse response time: ns/ ns (fall/rise) Integrated temperature sensor Small footprint LFCSP Power-down feature: <. mw at V Single-supply operation: 8 ma Fabricated using high speed SiGe process APPLICATIONS RF transmitter PA setpoint control and level monitoring RSSI measurement in base stations, WLAN, WiMAX, and radars GENERAL DESCRIPTION The AD88-EP is a demodulating logarithmic amplifier, capable of accurately converting an RF input signal to a corresponding decibel-scaled output voltage. It employs the progressive compression technique over a cascaded amplifier chain, each stage of which is equipped with a detector cell. The device is used in measurement or controller mode. The AD88-EP maintains accurate log conformance for signals of MHz to GHz and provides useful operation to 8 GHz. The input range is typically db (re: Ω) with error less than ± db. The AD88-EP has a ns response time that enables RF burst detection to beyond MHz. The device provides unprecedented logarithmic intercept stability vs. ambient temperature conditions. A mv/ C slope temperature sensor output is also provided for additional system monitoring. A single supply of V is required. Current consumption is typically 8 ma. Power consumption decreases to <. mw when the device is disabled. The AD88-EP can be configured to provide a control voltage to a VGA, such as a power amplifier or a measurement output, from Pin VOUT. Because the output can be used for controller applications, wideband noise is minimal. In this mode, the setpoint control voltage is applied to VSET. The feedback loop through an RF amplifier is closed via VOUT, the output of which regulates the amplifier output to a magnitude corresponding to VSET. The AD88-EP provides V to.9 V output capability at the VOUT pin, suitable for controller MHz to 8 GHz, 7 db Logarithmic Detector/Controller AD88-EP TEMP INHI INLO FUNCTIONAL BLOCK DIAGRAM VPSI ENBL TADJ VPSO TEMP SENSOR GAIN BIAS SLOPE DET DET DET DET CMIP Figure. I V VSET I V VOUT CMOP CLPF Figure. Typical Logarithmic Response and Error vs. Input Amplitude at.8 GHz applications. As a measurement device, Pin VOUT is externally connected to VSET to produce an output voltage, V OUT, which is a decreasing linear-in-db function of the RF input signal amplitude. The logarithmic slope is nominally mv/db but can be adjusted by scaling the feedback voltage from VOUT to the VSET interface. The intercept is dbm (re: Ω, CW input) using the INHI input. These parameters are very stable against supply and temperature variations. The AD88-EP is fabricated on a SiGe bipolar IC process and is available in a mm mm, -lead LFCSP. Performance is specified over a temperature range of o C to + o C. Additional application and technical information can be found in the AD88 data sheet Rev. 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 9, Norwood, MA -9, U.S.A. Tel: Fax: 78.. Analog Devices, Inc. All rights reserved.

2 AD88-EP TABLE OF CONTENTS Features... Applications... General Description... Functional Block Diagram... Revision History... Enhanced Product ESD Caution... Pin Configuration and Function Descriptions...7 Typical Performance Characteristics...8 Outline Dimensions... Ordering Guide... Specifications... Absolute Maximum Ratings... REVISION HISTORY 7/ Revision : Initial Version Rev. Page of

3 Enhanced Product AD88-EP SPECIFICATIONS V POS = V, C LPF = pf, T A = C,. Ω termination resistor at INHI, unless otherwise noted. Table. Parameter Test Conditions/Comments Min Typ Max Unit SIGNAL INPUT INTERFACE INHI (Pin ) and INLO (Pin ) Specified Frequency Range. 8 GHz DC Common-Mode Voltage V POS.8 V MEASUREMENT MODE VOUT (Pin ) shorted to VSET (Pin 7), sinusoidal input signal f = 9 MHz R TADJ = Ω Input Impedance 97.7 Ω pf ± db Dynamic Range T A = C db C < T A < + C db ± db Dynamic Range T A = C 7 db Maximum Input Level ± db error dbm Minimum Input Level ± db error 8 dbm Slope. mv/db Intercept 9. dbm Output Voltage High Power In P IN = dbm V Output Voltage Low Power In P IN = dbm... V Temperature Sensitivity P IN = dbm C T A C.7 db/ C C T A + C. db/ C f =.9 GHz R TADJ = Ω Input Impedance.8 Ω pf ± db Dynamic Range T A = C db C < T A < + C db ± db Dynamic Range T A = C 7 db Maximum Input Level ± db error dbm Minimum Input Level ± db error 9 dbm Slope 7. mv/db Intercept 7. dbm Output Voltage High Power In P IN = dbm..7.8 V Output Voltage Low Power In P IN = dbm... V Temperature Sensitivity P IN = dbm C T A C. db/ C C T A + C. db/ C f =. GHz R TADJ = Ω Input Impedance 9. Ω pf ± db Dynamic Range T A = C db C < T A < + C db ± db Dynamic Range T A = C 8 db Maximum Input Level ± db error dbm Minimum Input Level ± db error dbm Slope 8.. mv/db Intercept 9. dbm Output Voltage High Power In P IN = dbm..7.8 V Output Voltage Low Power In P IN = dbm... V Temperature Sensitivity P IN = dbm C T A C. db/ C C T A + C. db/ C Rev. Page of

4 AD88-EP Enhanced Product Parameter Test Conditions/Comments Min Typ Max Unit f =. GHz R TADJ = Ω Input Impedance 9.7 Ω pf ± db Dynamic Range T A = C 7 db C < T A < + C db ± db Dynamic Range T A = C 8 db Maximum Input Level ± db error dbm Minimum Input Level ± db error dbm Slope. mv/db Intercept 9.8 dbm Output Voltage High Power In P IN = dbm.77 V Output Voltage Low Power In P IN = dbm. V Temperature Sensitivity P IN = dbm C T A C. db/ C C T A + C.9 db/ C f =.8 GHz R TADJ = Ω Input Impedance.9 Ω pf ± db Dynamic Range T A = C 7 db C < T A < + C db ± db Dynamic Range T A = C 7 db Maximum Input Level ± db error dbm Minimum Input Level ± db error 8 dbm Slope. mv/db Intercept dbm Output Voltage High Power In P IN = dbm.8 V Output Voltage Low Power In P IN = dbm.9 V Temperature Sensitivity P IN = dbm C T A C.9 db/ C C T A + C.9 db/ C f = 8. GHz R TADJ = Ω ± db Dynamic Range T A = C db C < T A < + C 8 db Maximum Input Level ± db error dbm Minimum Input Level ± db error dbm Slope mv/db Intercept 7 dbm Output Voltage High Power In P IN = dbm. V Output Voltage Low Power In P IN = dbm.78 V Temperature Sensitivity P IN = dbm C T A C. db/ C C T A + C.78 db/ C OUTPUT INTERFACE VOUT (Pin ) Voltage Swing V SET = V; P IN = dbm, no load.9 V V SET =. V; P IN = dbm, no load mv Output Current Drive V SET =. V; P IN = dbm ma Small Signal Bandwidth P IN = dbm; from CLPF to VOUT MHz Video Bandwidth (or Envelope Bandwidth) MHz Output Noise P IN =. GHz; dbm, f NOISE = khz, C LPF = pf 9 nv/ Hz Fall Time P IN = Off to dbm, 9% to % ns Rise Time P IN = dbm to off, % to 9% ns Rev. Page of

5 Enhanced Product AD88-EP Parameter Test Conditions/Comments Min Typ Max Unit VSET INTERFACE VSET (Pin 7) Nominal Input Range P IN = dbm; measurement mode. P IN = dbm; measurement mode. V Logarithmic Scale Factor. db/mv Bias Current Source P IN = dbm; V SET =. V. μa TEMPERATURE REFERENCE TEMP (Pin ) Output Voltage T A = C, R LOAD = kω.7.. V Temperature Slope C T A + C, R LOAD = kω mv/ C Current Source/Sink T A = C /. ma POWER-DOWN INTERFACE ENBL (Pin ) Logic Level to Enable Device.7 V ENBL Current When Enabled ENBL = V < μa ENBL Current When Disabled ENBL = V; sourcing μa POWER INTERFACE VPSI (Pin and Pin ), VPSO (Pin 9) Supply Voltage.. V Quiescent Current ENBL = V 8 8 ma vs. Temperature C T A + C μa/ C Supply Current when Disabled ENBL = V, total currents for VPSI and VPSO μa vs. Temperature C T A + C μa Controller mode. Gain =. For other gains, see the AD88 data sheet. Rev. Page of

6 AD88-EP ABSOLUTE MAXIMUM RATINGS Table. Parameter Rating Supply Voltage: Pin VPSO, Pin VPSI.7 V ENBL, V SET Voltage to V POS Input Power (Single-Ended, re: Ω) dbm Internal Power Dissipation.7 W θ JA C/W Maximum Junction Temperature C Operating Temperature Range C to + C Storage Temperature Range C to + C Enhanced Product 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. ESD CAUTION With package die paddle soldered to thermal pads with vias connecting to inner and bottom layers. Rev. Page of

7 Enhanced Product AD88-EP PIN CONFIGURATION AND FUNCTION DESCRIPTIONS CMIP CMIP TADJ 9 VPSO TEMP CMOP 8 INHI VSET 7 AD88-EP INLO VOUT ENBL CLPF CMIP CMIP VPSI VPSI NOTES. THE EXPOSED PADDLE IS INTERNALLY CONNECTED TO CMIP (SOLDER TO GROUND). Figure. Pin Configuration 78- Table. Pin Function Descriptions Pin No. Mnemonic Description,,, CMIP Device Common (Input System Ground)., VPSI Positive Supply Voltage (Input System):. V to. V. Voltage on Pin, Pin, and Pin 9 should be equal. CLPF Loop Filter Capacitor. VOUT Measurement and Controller Output. 7 VSET Setpoint Input for Controller Mode or Feedback Input for Measurement Mode. 8 CMOP Device Common (Output System Ground). 9 VPSO Positive Supply Voltage (Output System):. V to. V. Voltage on Pin, Pin, and Pin 9 should be equal. TADJ Temperature Compensation Adjustment. TEMP Temperature Sensor Output. INHI RF Input. Nominal input range: dbm to dbm (re: Ω), ac-coupled. INLO RF Common for INHI. AC-coupled RF common. ENBL Device Enable. Connect to VPSI for normal operation. Connect pin to ground for disable mode. Paddle The Exposed Paddle is Internally Connected to CMIP (Solder to Ground). Rev. Page 7 of

8 AD88-EP Enhanced Product TYPICAL PERFORMANCE CHARACTERISTICS V POS = V; T A = + C, C, + C; C LPF = pf; R TADJ = Ω; unless otherwise noted. Colors: + C Black; C Blue; + C Red Figure. VOUT and Log Conformance vs. Input Amplitude at 9 MHz, Typical Device Figure. VOUT and Log Conformance vs. Input Amplitude at.9 GHz, Typical Device Figure 7. V OUT and Log Conformance vs. Input Amplitude at. GHz, Typical Device, R TADJ = Ω Figure 8. VOUT and Log Conformance vs. Input Amplitude at.8 GHz, Typical Device, R TADJ = Ω Figure. V OUT and Log Conformance vs. Input Amplitude at. GHz, Typical Device Figure 9. V OUT and Log Conformance vs. Input Amplitude at 8 GHz, Typical Device 78-9 Rev. Page 8 of

9 Enhanced Product AD88-EP V POS = V; T A = + C, C, + C; C LPF = pf; R TADJ = Ω; unless otherwise noted. Colors: + C Black; C Blue; + C Red. Figure. Distribution of Error over Temperature After Ambient Normalization vs. Input Amplitude at 9 MHz for at Least 7 Devices 78- Figure. Distribution of Error at Temperature After Ambient Normalization vs. Input Amplitude at. GHz for at Least 7 Devices, R TADJ = Ω 78- Figure. Distribution of Error at Temperature After Ambient Normalization vs. Input Amplitude at 9 MHz for at Least 7 Devices 78- Figure. Distribution of Error at Temperature After Ambient Normalization vs. Input Amplitude at.8 GHz for at Least 7 Devices, R TADJ = Ω 78- Figure. Distribution of Error at Temperature After Ambient Normalization vs. Input Amplitude at. GHz for at Least 7 Devices 78- Figure. Distribution of Error at Temperature After Ambient Normalization vs. Input Amplitude at 8 GHz for at Least 7 Devices 78- Rev. Page 9 of

10 AD88-EP Enhanced Product VPOS = V; TA = + C, C, + C; CLPF = pf; RTADJ = Ω; unless otherwise noted. Colors: + C Black; C Blue; + C Red. j j. j j. j... j. 8GHz START FREQUENCY =.GHz STOP FREQUENCY = 8GHz.8GHz.GHz j.9ghz.ghz.9ghz j.ghz Figure. Input Impedance vs. Frequency; No Termination Resistor on INHI, ZO = Ω NOISE SPECTRAL DENSITY (nv/ Hz) k RF OFF k dbm dbm dbm dbm dbm k k k FREQUENCY (khz) Figure 9. Noise Spectral Density of Output; CLPF = Open k 78-8 SUPPLY CURRENT (A) DECREASING V ENBL INCREASING V ENBL NOISE SPECTRAL DENSITY (nv/ Hz) V ENBL (V) Figure 7. Supply Current vs. Enable Voltage 78- k k k FREQUENCY (khz) Figure. Noise Spectral Density of Output Buffer (from CLPF to VOUT); CLPF =. μf 78-9 VOUT C C +8 C... mv/vertical DIVISION GND PULSED RF INPUT.GHz, dbm ns PER HORIZONTAL DIVISION Figure 8. VOUT Pulse Response Time; Pulsed RF Input. GHz, dbm; CLPF = Open Figure. Output Voltage Stability vs. Supply Voltage at.9 GHz When VP Varies by %, Multiple Devices 78- Rev. Page of

11 Enhanced Product AD88-EP OUTLINE DIMENSIONS PIN INDICATOR.. SQ.9. BSC... PIN INDICATOR EXPOSED PAD.. SQ SEATING PLANE TOP VIEW.7... MAX. NOM COPLANARITY.8. REF BOTTOM VIEW COMPLIANT TO JEDEC STANDARDS MO--WGGC MIN FOR PROPER CONNECTION OF THE EXPOSED PAD, REFER TO THE PIN CONFIGURATION AND FUNCTION DESCRIPTIONS SECTION OF THIS DATA SHEET. Figure. -Lead Lead Frame Chip Scale Package [LFCSP_WQ] mm mm Body, Very Very Thin Quad (CP--) Dimensions shown in millimeters 98-A ORDERING GUIDE Model, Temperature Range Package Description Package Option Ordering Quantity AD88SCPZ-EP-RL7 C to + C -Lead Lead Frame Chip Scale Package [LFCSP_WQ] CP--, AD88SCPZ-EP-R C to + C -Lead Lead Frame Chip Scale Package [LFCSP_WQ] CP-- AD88SCPZ-EP-WP C to + C -Lead Lead Frame Chip Scale Package [LFCSP_WQ] CP-- AD88-EP-EVALZ Evaluation Board Z = RoHS Compliant Part. WP = waffle pack. Rev. Page of

1 MHz to 10 GHz, 45 db Log Detector/Controller AD8319

1 MHz to 10 GHz, 45 db Log Detector/Controller AD8319 FEATURES Wide bandwidth: 1 MHz to 10 GHz High accuracy: ±1.0 db over temperature 45 db dynamic range up to 8 GHz Stability over temperature: ±0.5 db Low noise measurement/controller output VOUT Pulse response