50 MHz to 1000 MHz Quadrature Demodulator AD8348 FEATURES ENBL 15 VREF IMXO IOFS IAIN IOPP IOPN 14 8 13 6 4 3 BIAS CELL VREF 5 VCMO 1 LOIP 28 LOIN VCMO IFIP 11 DIVIDE BY 2 IFIN 10 PHASE SPLITTER AD8348 VGIN 17 GAIN CONTROL VCMO 18 19 24 MXIP MXIN ENVG 21 16 23 QXMO QOFS QAIN 25 26 QOPP QOPN 03678-001 Integrated I/Q demodulator with IF VGA amplifier Operating IF frequency 50 MHz to 1000 MHz (3 dB IF BW of 500 MHz driven from RS = 200 ) Demodulation bandwidth 75 MHz Linear-in-decibel AGC range 44 dB Third-order intercept IIP3 +28 dBm @ minimum gain (FIF = 380 MHz) IIP3 -8 dBm @ maximum gain (FIF = 380 MHz) Quadrature demodulation accuracy Phase accuracy 0.5 Amplitude balance 0.25 dB Noise figure 11 dB @ maximum gain (FIF = 380 MHz) LO input -10 dBm Single supply 2.7 V to 5.5 V Power-down mode Compact, 28-lead TSSOP package FUNCTIONAL BLOCK DIAGRAM Figure 1. APPLICATIONS QAM/QPSK demodulator W-CDMA/CDMA/GSM/NADC Wireless local loop LMDS GENERAL DESCRIPTION The AD8348 is a broadband quadrature demodulator with an integrated intermediate frequency (IF), variable gain amplifier (VGA), and integrated baseband amplifiers. It is suitable for use in communications receivers, performing quadrature demodulation from IF directly to baseband frequencies. The baseband amplifiers are designed to interface directly with dual-channel ADCs, such as the AD9201, AD9283, and AD9218, for digitizing and postprocessing. The IF input signal is fed into two Gilbert cell mixers through an X-AMP(R) VGA. The IF VGA provides 44 dB of gain control. A precision gain control circuit sets a linear-in-decibel gain characteristic for the VGA and provides temperature compensation. The LO quadrature phase splitter employs a divide-by-2 frequency divider to achieve high quadrature accuracy and amplitude balance over the entire operating frequency range. Optionally, the IF VGA can be disabled and bypassed. In this mode, the IF signal is applied directly to the quadrature mixer inputs via the MXIP and MXIN pins. Separate I- and Q-channel baseband amplifiers follow the baseband outputs of the mixers. The voltage applied to the VCMO pin sets the dc common-mode voltage level at the baseband outputs. Typically, VCMO is connected to the internal VREF voltage, but it can also be connected to an external voltage. This flexibility allows the user to maximize the input dynamic range to the ADC. Connecting a bypass capacitor at each offset compensation input (IOFS and QOFS) nulls dc offsets produced in the mixer. Offset compensation can be overridden by applying an external voltage at the offset compensation inputs. The mixers' outputs are brought off-chip for optional filtering before final amplification. Inserting a channel selection filter before each baseband amplifier increases the baseband amplifiers' signal handling range by reducing the amplitude of high level, out-of-channel interferers before the baseband signal is fed into the I/Q baseband amplifiers. The single-ended mixer output is amplified and converted to a differential signal for driving ADCs. Rev. A 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 (c)2006 Analog Devices, Inc. All rights reserved. AD8348 TABLE OF CONTENTS Features .............................................................................................. 1 Enable........................................................................................... 18 Applications....................................................................................... 1 Baseband Offset Cancellation................................................... 18 Functional Block Diagram .............................................................. 1 Applications..................................................................................... 20 General Description ......................................................................... 1 Basic Connections...................................................................... 20 Revision History ............................................................................... 2 Power Supply............................................................................... 20 Specifications..................................................................................... 3 Device Enable ............................................................................. 20 Absolute Maximum Ratings............................................................ 6 VGA Enable ................................................................................ 20 ESD Caution.................................................................................. 6 Gain Control ............................................................................... 20 Pin Configuration and Function Descriptions............................. 7 LO Inputs..................................................................................... 20 Equivalent Circuits ........................................................................... 9 IF Inputs ...................................................................................... 20 Typical Performance Characteristics ........................................... 11 MX Inputs ................................................................................... 20 VGA and Demodulator ............................................................. 11 Baseband Outputs ...................................................................... 21 Demodulator Using MXIP and MXIN.................................... 14 Output DC Bias Level ................................................................ 21 Final Baseband Amplifiers ........................................................ 15 Interfacing to Detector for AGC Operation............................... 21 VGA/Demodulator and Baseband Amplifier......................... 16 Baseband Filters.......................................................................... 22 Theory of Operation ...................................................................... 18 LO Generation ............................................................................ 23 VGA.............................................................................................. 18 Evaluation Board ........................................................................ 23 Downconversion Mixers ........................................................... 18 Outline Dimensions ....................................................................... 28 Phase Splitter............................................................................... 18 Ordering Guide .......................................................................... 28 I/Q Baseband Amplifiers........................................................... 18 REVISION HISTORY 4/06--Rev. 0 to Rev. A Updated Format..................................................................Universal Changes to Specifications ................................................................ 3 Changes to IF Inputs Section ........................................................ 20 Changes to Evaluation Board Section.......................................... 23 Changes to Table 6.......................................................................... 27 Changes to Ordering Guide .......................................................... 28 8/03--Revision 0: Initial Version Rev. A | Page 2 of 28 AD8348 SPECIFICATIONS VS = 5 V, TA = 25oC, FLO = 380 MHz, FIF = 381 MHz, PLO = -10 dBm, RS (LO) = 50 , RS (IFIP and MXIP/MXIN) = 200 , unless otherwise noted. Table 1. Parameter OPERATING CONDITIONS LO Frequency Range IF Frequency Range Baseband Bandwidth LO Input Level VSUPPLY (VS) Temperature Range IF FRONT END WITH VGA Input Impedance Gain Control Range Maximum Conversion Voltage Gain Minimum Conversion Voltage Gain 3 dB Bandwidth Gain Control Linearity IF Gain Flatness Input 1 dB Compression Point (P1dB) Second-Order Input Intercept (IIP2) Third-Order Input Intercept (IIP3) LO Leakage Demodulation Bandwidth Quadrature Phase Error 1 Conditions Min External input = 2 x LO frequency 100 50 50 source -12 2.7 -40 IFIP to IMXO (QMXO), ENVG = 5 V, IMXO/QMXO load = 1.5 k Measured differentially across MXIP/MXIN Unit 2000 1000 MHz MHz MHz dBm V C 0 5.5 +85 ||pF dB dB dB MHz dB dB p-p dB p-p VGIN = 0.2 V (maximum gain) VGIN = 1.2 V (maximum gain) IF1 = 385 MHz, IF2 = 386 MHz +3 dBm each tone from 200 source, VGIN = 1.2 V (minimum gain) -42 dBm each tone from 200 source, VGIN = 0.2 V (maximum gain) IF1 = 381 MHz, IF2 = 381.02 MHz Each tone 10 dB below P1dB from 200 source, VGIN = 1.2 V (minimum gain) Each tone 10 dB below P1dB from 200 source, VGIN = 0.2 V (maximum gain) -22 +13 dBm dBm 65 dBm 18 dBm 28 dBm -8 dBm Measured at IFIP, IFIN Measured at IMXO/QMXO (LO = 50 MHz) Small signal 3 dB bandwidth LO = 380 MHz (LOIP/LOIN 760 MHz) vs. temperature vs. baseband frequency (dc to 30 MHz) -80 -60 75 0.1 -0.0032 +0.01 0.05 0 0.0125 10.75 dBm dBm MHz Degrees /C /MHz dB dB/C dB dB VGIN = 0.2 V (maximum voltage gain) VGIN = 1.2 V (minimum voltage gain) VGIN = 0.4 V (+21 dB) to 1.1 V (-14 dB) FIF = 380 MHz 5% (VGIN = 1.2 V) FIF = 900 MHz 5% (VGIN = 1.2 V) -0.7 -0.3 vs. temperature vs. baseband frequency (dc to 30 MHz) Maximum gain, from 200 source, FIF = 380 MHz Mixer Output Impedance Capacitive Load Resistive Load Mixer Peak Output Current 75 -10 Max 200||1.1 44 25.5 -18.5 500 0.5 0.1 1.3 I/Q Amplitude Imbalance1 Noise Figure (Double Sideband) Typ +0.7 +0.3 40 Shunt from IMXO, QMXO to VCMO Shunt from IMXO, QMXO to VCMO Rev. A | Page 3 of 28 0 200 10 1.5 2.5 pF k mA AD8348 Parameter IF FRONT END WITHOUT VGA Input Impedance Conversion voltage Gain 3 dB Output Bandwidth IF Gain Flatness Input 1 dB Compression Point (P1dB) Third-Order Input Intercept (IIP3) LO Leakage Demodulation Bandwidth Quadrature Phase Error I/Q Amplitude Imbalance Noise Figure (Double Sideband) I/Q BASEBAND AMPLIFIER Gain Bandwidth Output DC Offset (Differential) Output Common-Mode Offset Group Delay Flatness Input-Referred Noise Voltage Output Swing Limit (Upper) Output Swing Limit (Lower) Peak Output Current Input Impedance Input Bias Current RESPONSE FROM IF AND MX INPUTS TO BASEBAND AMPLIFIER OUTPUT Gain CONTROL INPUT/OUTPUTS VCMO Input Range VREF Output Voltage Gain Control Voltage Range Gain Slope Gain Intercept Gain Control Input Bias Current LO INPUTS LOIP Input Return Loss Conditions From MXIP, MXIN to IMXO (QMXO), ENVG = 0 V, IMXO/QMXO load = 1.5 k Measured differentially across MXIP/MXIN Min FIF = 380 MHZ 5% FIF = 900 MHZ 5% IF1 = 381 MHz, IF2 = 381.02 MHz Each tone 10 dB below P1dB from 200 source Measured at MXIP/MXIN Measured at IMXO, QMXO Small signal 3 dB bandwidth LO = 380 MHz (LOIP/LOIN 760 MHz, single-ended) -2 From 200 source, FIF = 380 MHz From IAIN to IOPP/IOPN and QAIN to QOPP/ QOPN, RLOAD = 2 k, single-ended to ground 10 pF differential load LO leakage offset corrected using 500 pF capacitor on IOFS, QOFS (VIOPP - VIOPN) (VIOPP + VIOPN)/2 - VCMO 0 MHz to 50 MHz Frequency = 1 MHz -50 -75 Typ Max 200||1.5 10.5 75 0.1 0.15 -4 14 ||pF dB MHz dB p-p dB p-p dBm dBm -70 -60 75 0.5 dBm dBm MHz Degrees +2 0.25 21 dB dB 20 125 12 dB MHz mV 35 3 8 +50 +75 1 50||1 2 mV ns p-p nV/Hz V V mA k||pF A 30.5 45.5 1.5 dB dB dB VS -1 0.5 IMXO and QMXO connected directly to IAIN and QAIN, respectively From MXIP/MXIN From IFIP/IFIN, VGIN = 0.2 V From IFIP/IFIN, VGIN = 1.2 V VS = 5 V VS = 2.7 V VGIN Linear extrapolation back to theoretical gain at VGIN = 0 V LOIN ac-coupled to ground (760 MHz applied to LOIP) Rev. A | Page 4 of 28 0.5 0.5 0.95 0.2 -55 55 Unit 1 1 1 -50 61 4 1.7 1.05 1.2 -45 67 V V V V dB/V dB 1 A -6 dB AD8348 Parameter POWER-UP CONTROL ENBL Threshold Low ENBL Threshold High Input Bias Current Power-Up Time Power-Down Time POWER SUPPLIES Voltage Current (Enabled) Current (Standby) 1 Conditions Min Typ Max Unit Low = standby High = enable 0 VS - 1 VS/2 VS/2 2 45 1 VS V V A s Time for final baseband amplifiers to be within 90% of final amplitude Time for supply current to be <10% of enabled value VPOS1, VPOS2, VPOS3 VS = 5 V, VENBL = 5 V VS = 5 V, VENBL = 0 V These parameters are guaranteed but not tested in production. Limits are 6 from the mean. Rev. A | Page 5 of 28 700 2.7 38 48 75 ns 5.5 58 V mA A AD8348 ABSOLUTE MAXIMUM RATINGS Table 2. Parameter Supply Voltage on VPOS1, VPOS2, VPOS3 Pins LO Input Power IF Input Power Internal Power Dissipation JA Maximum Junction Temperature Operating Temperature Range Storage Temperature Range Lead Temperature (Soldering, 60 sec) Rating 5.5 V 10 dBm (re: 50 ) 18 dBm (re: 200 ) 450 mW 68C/W 150C -40C to +85C -65C to +125C 300C 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 ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on the human body and test equipment and can discharge without detection. Although this product features proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance degradation or loss of functionality. Rev. A | Page 6 of 28 AD8348 PIN CONFIGURATION AND FUNCTION DESCRIPTIONS LOIP 1 IOPN 3 IOPP 4 VCMO 5 IAIN 6 28 LOIN AD8348 27 COM1 TOP VIEW (Not to Scale) 26 QOPN 25 QOPP 24 ENVG 23 QAIN COM3 7 22 COM3 IMXO 8 21 QMXO COM2 9 20 VPOS3 IFIN 10 19 MXIN IFIP 11 18 MXIP VPOS2 12 17 VGIN IOFS 13 16 QOFS VREF 14 15 ENBL 03678-002 VPOS1 2 Figure 2. 28-Lead TSSOP Pin Configuration Table 3. Pin Function Descriptions--28-Lead TSSOP Pin No. 1, 28 Mnemonic LOIP, LOIN 2, 12, 20 5 VPOS1, VPOS2, VPOS3 IOPN, IOPP, QOPP, QOPN VCMO 6, 23 IAIN, QAIN 7, 22 8, 21 COM3 IMXO, QMXO 9 10, 11 COM2 IFIN, IFIP 13, 16 IOFS, QOFS 14 VREF 3, 4, 25, 26 Description LO Inputs. For optimum performance, these inputs should be ac-coupled and driven differentially. Differential drive from single-ended sources can be achieved via a balun. To obtain a broadband 50 input impedance, connect a 60.4 shunt resistor between LOIP and LOIN. Typical input drive level is equal to -10 dBm. Positive Supply for LO, IF, and Biasing and Baseband Sections, Respectively. These pins should be decoupled with 0.1 F and 100 pF capacitors. I- and Q-Channel Differential Baseband Outputs. Typical output swing is equal to 2 V p-p differential. The dc common-mode voltage level on these pins is set by the voltage on VCMO. Baseband DC Common-Mode Voltage. The voltage applied to this pin sets the dc common-mode levels for all the baseband outputs and inputs (IMXO, QMXO, IOPP, IOPN, QOPP, QOPN, IAIN, and QAIN). This pin can be connected either to VREF or to a reference voltage from another device (typically an ADC). I- and Q-Channel Baseband Amplifier Inputs. The single-ended signals on these pins are referenced to VCMO and must have a dc bias equal to the dc voltage on the VCMO pin. If IMXO (QMXO) is dc-coupled to IAIN (QAIN), biasing will be provided by IMXO (QMXO). If an ac-coupled filter is placed between IMXO and IAIN, these pins can be biased from the source driving VCMO through a 1 k resistor. The gain from IAIN/QAIN to the differential outputs (IOPP/IOPN and QOPP/QOPN) is 20 dB. Ground for Biasing and Baseband Sections. I- and Q-Channel Mixer Baseband Outputs. These are low impedance (40 ) outputs whose bias levels are set by the voltage applied to the VCMO pin. These pins are typically connected to IAIN and QAIN, respectively, either directly or through a filter. Each output can drive a maximum current of 2.5 mA. IF Section Ground. IF Inputs. IFIN should be ac-coupled to ground. The single-ended IF input signal should be ac-coupled into IFIP. The nominal differential input impedance of these pins is 200 . For a broadband 50 input impedance, a minimum-loss L pad should be used; RSERIES = 174 , RSHUNT = 57.6 . This provides a 200 source impedance to the IF input. However, the AD8348 does not necessarily require a 200 source impedance, and a single shunt 66.7 resistor can be placed between IFIP and IFIN. I- and Q-Channel Offset Nulling Inputs. DC offsets on the I-channel mixer output (IMXO) can be nulled by connecting a 0.1 F capacitor from IOFS to ground. Driving IOFS with a fixed voltage (typically a DAC calibrated such that the offset at IOPP/IOPN is nulled) can extend the operating frequency range to include dc. The QOFS pin can likewise be used to null offsets on the Q-channel mixer output (QMXO). Reference Voltage Output. This output voltage (1 V) is the main bias level for the device and can be used to externally bias the inputs and outputs of the baseband amplifiers. The typical maximum drive current for this output is 2 mA. Rev. A | Page 7 of 28 Equivalent Circuit A B C D H E F G AD8348 Pin No. 15 17 Mnemonic ENBL VGIN 18, 19 MXIP, MXIN 24 ENVG 27 COM1 Description Chip Enable Input. Active high. Threshold is equal to VS/2. Gain Control Input. The voltage on this pin controls the gain on the IF VGA. The gain control voltage range is from 0.2 V to 1.2 V and corresponds to a conversion gain range from +25.5 dB to -18.5 dB. This is the gain to the output of the mixers (that is, IMXO and QMXO). There is an additional 20 dB of fixed gain in the final baseband amplifiers (IAIN to IOPP/IOPN and QAIN to QOPP/QOPN). Note that the gain control function has a negative sense (that is, increasing voltage decreases gain). Auxiliary Mixer Inputs. If ENVG is low, the IFIP and IFIN inputs are disabled and MXIP and MXIN are enabled, allowing the VGA to be bypassed. The auxiliary mixer inputs are fully differential inputs that should be ac-coupled to the signal source. Active High VGA Enable. When ENVG is high, IFIP and IFIN inputs are enabled and MXIP and MXIN inputs are disabled. When ENVG is low, MXIP and MXIN inputs are enabled and IFIP and IFIN inputs are disabled. LO Section Ground. Rev. A | Page 8 of 28 Equivalent Circuit D D I D AD8348 EQUIVALENT CIRCUITS VPOS1 VPOS3 LOIN LOIP COM1 03678-006 03678-003 IAIN, QAIN, VGIN, ENBL, ENVG COM3 Figure 3. Circuit A Figure 6. Circuit D VPOS3 VPOS2 IFIP IOPP, IOPN, QOPP, QOPN IFIN 03678-007 COM3 03678-004 VCMO COM3 Figure 7. Circuit E Figure 4. Circuit B VPOS3 50A MAX VPOS3 03678-005 COM3 COM3 Figure 5. Circuit C Figure 8. Circuit F Rev. A | Page 9 of 28 03678-008 IOFS, QOFS VCMO AD8348 VPOS3 VPOS2 MXIP VREF COM2 COM3 Figure 9. Circuit G Figure 11. Circuit I VPOS3 COM3 03678-010 IMXO, QMXO Figure 10. Circuit H Rev. A | Page 10 of 28 03678-011 03678-009 MXIN AD8348 TYPICAL PERFORMANCE CHARACTERISTICS VGA AND DEMODULATOR 3 20 LINERR T = +25C, VPOS = 2.7V, FREQ = 900MHz 3 2 15 LINERR T = -40C, VPOS = 2.7V, FREQ = 900MHz 2 15 1 10 0 5 -1 -2 0 -5 T = +85C, VPOS = 5V, FREQ = 380MHz T = +25C, VPOS = 5V, FREQ = 380MHz -10 -15 -20 0.2 -3 -4 -5 T = -40C, VPOS = 5V, FREQ = 380MHz 0.3 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 1.1 LINERR T = -40C, VPOS = 5V, FREQ = 900MHz -2 T = +85C, VPOS = 2.7V, FREQ = 900MHz -3 T = +25C, VPOS = 2.7V, FREQ = 900MHz -15 -4 -5 T = -40C, VPOS = 2.7V, FREQ = 900MHz -25 0.2 0.3 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 -6 1.2 1.1 Figure 15. Mixer Gain and Linearity Error vs. VGIN, VPOS = 2.7 V, FIF = 900 MHz, FBB = 1 MHz, Temperature = -40C, +25C, +85C 26 5 0 0 -1 -2 T = +85C, VPOS = 5V, FREQ = 900MHz -3 -10 T = +25C, VPOS = 5V, FREQ = 900MHz VGA AND MIXER GAIN (dB) VGA AND MIXER GAIN (dB) 1 -15 -5 2 10 -5 -1 3 LINERR T = +25C, VPOS = 5V, FREQ = 900MHz 15 0 0 28 LINEARITY ERROR (dB) 20 5 -10 4 LINERR T = +85C, VPOS = 5V, FREQ = 900MHz 1 -20 -6 1.2 Figure 12. Mixer Gain and Linearity Error vs. VGIN, VPOS = 5 V, FIF = 380 MHz, FBB = 1 MHz, Temperature = -40C, +25C, +85C 25 10 LINEARITY ERROR (dB) VGA AND MIXER GAIN (dB) LINERR T = -40C, VPOS = 5V, FREQ = 380MHz 4 LINERR T = +85C, VPOS = 2.7V, FREQ = 900MHz 03678-015 LINERR T = +25C, VPOS = 5V, FREQ = 380MHz 20 25 VGA AND MIXER GAIN (dB) 25 4 LINEARITY ERROR (dB) LINERR T = +85C, VPOS = 5V, FREQ = 380MHz 03678-012 30 -4 24 5V, 0.2V, +25C 22 2.7V, 0.2V, +25C 5V, 0.2V, +85C 2.7V, 0.2V, +85C 20 5V, 0.2V, -40C 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 1.1 18 Figure 13. Mixer Gain and Linearity Error vs. VGIN, VPOS = 5 V, FIF = 900 MHz, FBB = 1 MHz, Temperature = -40C, +25C, +85C LINERR T = -40C, VPOS = 2.7V, FREQ = 380MHz 1 10 0 5 -1 0 -2 T = +85C, VPOS = 2.7V, FREQ = 380MHz -5 -10 -20 0.2 -3 T = +25C, VPOS = 2.7V, FREQ = 380MHz -15 -4 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 800 900 1000 5V, 1.2V, +85 C 2.7V, 1.2V, +85 C -20 5V, 1.2V, -40C 2.7V, 1.2V, +25C 2.7V, 1.2V, -40C -25 5V, 1.2V, +25 C -5 T = -40C, VPOS = 2.7V, FREQ = 380MHz 0.3 400 500 600 700 IF FREQUENCY (MHz) 2 15 VGA AND MIXER GAIN (dB) VGA AND MIXER GAIN (dB) 20 300 3 LINEARITY ERROR (dB) 25 -15 4 LINERR T = +85C, VPOS = 2.7V, FREQ = 380MHz LINERR T = +25C, VPOS = 2.7V, FREQ = 380MHz 200 Figure 16. Gain vs. FIF, VGIN = 0.2 V, FBB = 1 MHz, Temperature = -40C, +25C, +85C 1.0 1.1 -6 1.2 03678-014 30 100 03678-016 0.3 2.7V, 0.2V, -40C -6 1.2 Figure 14. Mixer Gain and Linearity Error vs. VGIN, VPOS = 2.7 V, FIF = 380 MHz, FBB = 1 MHz, Temperature = -40C, +25C, +85C Rev. A | Page 11 of 28 -30 100 200 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 Figure 17. Gain vs. FIF, VGIN = 1.2 V, FBB = 1 MHz, Temperature = -40C, +25C, +85C 1000 03678-017 -25 0.2 -5 T = -40C, VPOS = 5V, FREQ = 900MHz 03678-013 -20 AD8348 26 VGA AND MIXER GAIN (dB) 25 2.7V, 0.2V, +85C 24 5V, 0.2V, -40C 2.7V, 0.2V, +25C 23 2.7V, 0.2V, -40C 22 5V, 0.2V, +85C 21 20 19 17 0 10 20 30 40 50 60 70 80 BASEBAND FREQUENCY (MHz) 90 03678-018 18 100 Figure 18. Gain vs. FBB, VGIN = 0.2 V, FIF = 380 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C INPUT 1dB COMPRESSION POINT (dBm) (re 200) 20 5V, 0.2V, +25C -40C, 5V, 900MHz 15 +25C, 2.7V, 900MHz 10 +25C, 5V, 900MHz 5 +85C, 2.7V, 900MHz 0 -5 +85C, 5V, 900MHz -10 -15 -20 0.2 -40C, 2.7V, 900MHz 0.3 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 1.1 1.2 03678-021 27 Figure 21. Input 1 dB Compression Point (IP1dB) vs. VGIN, FIF = 900 MHz, FBB = 1 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C -17 30 29 5V, 1.2V, +85C -20 5V, 1.2V, +85C 2.7V, 1.2V, +25C 5V, 1.2V, +25C -23 2.7V, 1.2V, -40C 10 20 30 40 50 60 70 80 BASEBAND FREQUENCY (MHz) 90 100 Figure 19. Gain vs. FBB, VGIN = 1.2 V, FIF = 380 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C 2.7V, 1.2V, +25C 5V, 1.2V, -40C 2.7V, 1.2V, -40C 100 200 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 1000 Figure 22. IIP3 vs. FIF, VGIN = 1.2 V, FBB = 1 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C, Tone Spacing = 20 kHz 15 0 +25C, 5V, 380MHz 10 5V, 0.2V, +85C -40C, 5V, 380MHz 2.7V, 0.2V, +85C +25C, 2.7V, 380MHz 0 +85C, 2.7V, 380MHz -5 -10 INPUT IIP3 (dBm) (re 200) 5 +85C, 5V, 380MHz -15 -5 2.7V, 0.2V, +25C 5V, 0.2V, -40C -10 5V, 0.2V, +25C 2.7V, 0.2V, -40C -20 0.3 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 1.1 1.2 Figure 20. Input 1 dB Compression Point (IP1dB) vs. VGIN, FIF = 380 MHz, FBB = 1 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C Rev. A | Page 12 of 28 -15 100 200 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 1000 Figure 23. IIP3 vs. FIF, VGIN = 0.2 V, FBB = 1 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C 03678-023 -40C, 2.7V, 380MHz -25 0.2 03678-020 INPUT 1dB COMPRESSION POINT (dBm) (re 200) 2.7V, 1.2V, +85C 26 24 03678-019 0 27 5V, 1.2V, +25C 25 5V, 1.2V, -40C -26 28 03678-022 INPUT IIP3 (dBm) (re 200) VGA AND MIXER GAIN (dB) 2.7V, 1.2V, +85C AD8348 32 45 35 2.7V, 1.2V, +85C 5V, 1.2V, +25C 26 5V, 1.2V, +85C 10 20 30 40 50 60 70 80 BASEBAND FREQUENCY (MHz) 90 100 30 20 25 15 20 10 15 5 10 0 5 -5 0 0.2 Figure 24. IIP3 vs. FBB, VGIN = 1.2 V, FIF = 380 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 1.1 -10 1.2 Figure 27. Noise Figure and IIP3 vs. VGIN, Temperature = 25C, FIF = 380 MHz, FBB = 1 MHz, VPOS = 2.7 V 40 0 2.7V, 0.2V, +85C VGA AND MIXER INPUT IIP3 (dBm) (re 200) 0.3 35 NF 35 30 5V, 0.2V, +85C 25 30 NOISE FIGURE (dB) -5 5V, 0.2V, +25C -10 2.7V, 0.2V, -40C 5V, 0.2V, -40C -15 IIP3 20 25 15 20 10 15 5 10 0 2.7V, 0.2V, +25C 5 0 10 20 30 40 50 60 70 80 BASEBAND FREQUENCY (MHz) 90 100 -5 0 0.2 03678-025 -20 Figure 25. IIP3 vs. FBB, VGIN = 0.2 V, FIF = 380 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C INPUT IIP3 (dBm) (re 200) 0 03678-024 22 25 IIP3 INPUT IIP3 (dBm) (re 200) NOISE FIGURE (dB) 35 28 24 30 NF 03678-027 40 5V, 1.2V, -40C 2.7V, 1.2V, +25C 30 0.3 0.4 0.5 0.6 0.7 0.8 VGIN (V) 0.9 1.0 1.1 -10 1.2 03678-028 VGA AND MIXER INPUT IIP3 (dBm) (re 200) 2.7V, 1.2V, -40C Figure 28. Noise Figure and IIP3 vs. VGIN, Temperature = 25C, FIF = 380 MHz, FBB = 1 MHz, VPOS = 5 V 16 16 15 15 2.0 1.5 NF @ LO = 900MHz 11 850 950 Figure 26. Noise Figure vs. FIF, T = 25C, VGIN = 0.2 V, FBB = 1 MHz -0.5 NF @ LO = 380MHz 9 750 0 11 9 350 450 550 650 IF FREQUENCY (MHz) 0.5 PHASE ERROR 900MHz 10 250 PHASE ERROR 380MHz 12 10 150 PHASE ERROR 50MHz 8 -12 -1.0 -1.5 NF @ LO = 50MHz -10 -8 -6 -4 LO INPUT LEVEL (V) PHASE ERROR (Degrees) 12 13 -2 0 -2.0 03678-029 NOISE FIGURE (dB) 13 8 50 1.0 14 NF VGIN = 0.2V 03678-026 NOISE FIGURE (dB) 14 Figure 29. Noise Figure and Quadrature Phase Error IMXO/QMXO vs. LO Input Level, Temperature = 25C, VGIN = 0.2 V, VPOS = 5 V for FIF = 50 MHz, 380 MHz, and 900 MHz Rev. A | Page 13 of 28 AD8348 DEMODULATOR USING MXIP AND MXIN 18 11.0 23.0 TEMP = +25C, VPOS = 5V TEMP = +85C, VPOS = 2.7V 9.0 TEMP = +25C, VPOS = 2.7V 8.5 8.0 100 200 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 1000 MIXER INPUT P1dB (dBm) (re 200) TEMP = +25C, VPOS = 5V -3.0 TEMP = -40C, VPOS = 5V -3.5 -4.0 -4.5 TEMP = +85C, VPOS = 2.7V TEMP = -40C, VPOS = 2.7V -6.0 TEMP = +25C, VPOS = 2.7V -6.5 -7.0 100 200 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 1000 03678-031 -7.5 -8.0 22.0 15 21.5 14 21.0 IIP3 5V 13 20.5 NF 2.7V 12 20.0 19.5 IIP3 2.7V 150 250 350 450 550 650 IF FREQUENCY (MHz) 750 850 950 19.0 Figure 32. IIP3 and Noise Figure vs. FIF, VPOS = 2.7 V, 5 V, Temperature = 25C TEMP = +85C, VPOS = 5V -2.5 -5.5 16 10 50 -1.5 -5.0 22.5 11 TEMP = +85C, VPOS = 5V Figure 30. Mixer Gain vs. FIF, VPOS = 2.7 V, 5 V, FBB = 1 MHz, Temperature = -40C, +25C, +85C -2.0 17 03670-032 TEMP = -40C, VPOS = 5V 10.0 9.5 INPUT IIP3 (dBm) (re 200) TEMP = -40C, VPOS = 2.7V 03678-030 MIXER GAIN (dB) 10.5 NOISE FIGURE (dB) NF 5V Figure 31. Input 1 dB Compression Point vs. FIF, FBB = 1 MHz, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C Rev. A | Page 14 of 28 AD8348 FINAL BASEBAND AMPLIFIERS 21 35 -40C, 5V -40C, 2.7V 20 +85C, 5V +85C, 5V 20 +25C, 5V OIP3 (dBV) 18 GAIN (dB) +25C, 5V 25 +25C, 2.7V 19 -40C, 5V 30 +85C, 2.7V 17 16 +85C, 2.7V 15 10 5 +25C, 2.7V 0 15 -5 14 1000 -15 10 03678-033 1 10 100 BASEBAND FREQUENCY (MHz) Figure 33. Gain vs. FBB, VVCMO = VREF = 1 V, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C +25C, 5V -40C, 5V 30 50 70 90 110 130 150 BASEBAND FREQUENCY (MHz) 170 190 03678-035 -10 13 0.1 5 -40C, 2.7V Figure 35. OIP3 vs. FBB, VVCMO = VREF = 1 V, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C 10 +85C, 5V OP1dB (dBV) +25C, 2.7V -5 -40C, 2.7V +85C, 2.7V -10 -20 0.1 1 10 100 BASEBAND FREQUENCY (MHz) 1000 03678-034 -15 Figure 34. OP1dB Compression vs. FBB, VVCMO = VREF = 1 V, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C Rev. A | Page 15 of 28 8 7 6 5 4 3 2 1 0 1 10 100 1000 FREQUENCY (kHz) 10000 Figure 36. Noise Spectral Density 100000 03678-036 BASEBAND AMPLIFIER INPUT NOISE SPECTRAL DENSITY (nV/ Hz) 9 0 AD8348 2.0 1.5 1.5 I/Q AMPLITUDE MISMATCH (dB) 2.0 1.0 2.7V, 0.2V, -40C 0.5 5V, 0.2V, +85C 0 5V, 0.2V, -40C 2.7V, 0.2V, +85C -0.5 2.7V, 0.2V, +25C 5V, 0.2V, +25C -1.0 -1.5 0 -0.5 -1.0 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 1000 -2.0 200 300 400 500 600 700 IF FREQUENCY (MHz) 800 900 1000 Figure 40. I/Q Amplitude Imbalance vs. FIF, Temperature = 25C, VPOS = 5 V 2.0 2.7V, 0.7V, +25C 1.5 100 300 2.2 280 2.0 260 1.8 240 1.6 SHUNT RESISTANCE () 2.7V, 0.7V, -40C 1.0 5V, 0.7V, -40C 0.5 0 5V, 0.7V, +85C -0.5 5V, 0.7V, +25C -1.0 2.7V, 0.7V, +85C 0 5 10 15 20 25 30 BASEBAND FREQUENCY (MHz) 35 40 03678-038 -1.5 03678-040 200 1.4 220 SHUNT CAPACITANCE 200 180 1.2 1.0 SHUNT RESISTANCE 160 0.8 140 0.6 120 0.4 100 50 Figure 38. Quadrature Phase Error vs. FBB, VGIN = 0.7 V, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C, FIF = 380 MHz 150 250 350 450 550 650 IF FREQUENCY (MHz) 750 850 950 SHUNT CAPACITANCE (pF) 100 Figure 37. Quadrature Phase Error vs. FIF, VGIN = 0.7 V, VPOS = 2.7 V, 5 V, Temperature = -40C, +25C, +85C QUADRATURE PHASE ERROR (Degrees) 0.5 0.2 03678-041 -2.0 -2.0 1.0 -1.5 03678-037 QUADRATURE PHASE ERROR (Degrees) VGA/DEMODULATOR AND BASEBAND AMPLIFIER Figure 41. Input Impedance of IF Input vs. FIF, VGIN = 0.7 V, VPOS = 5 V 90 60 120 0.4 I/Q AMPLITUDE MISMATCH (dB) 150 30 0.2 180 5V, 0.7V, 25C 0 0 IFIP WITH L PAD 210 330 IFIP WITHOUT L PAD -0.2 IMPEDANCE CIRCLE 240 5 10 15 20 25 30 BASEBAND FREQUENCY (MHz) 35 40 Figure 39. I/Q Amplitude Imbalance vs. FBB, Temperature = 25C, VPOS = 5 V Rev. A | Page 16 of 28 300 270 03678-042 0 03678-039 -0.4 Figure 42. S11 of IF Input vs. FIF, FIF = 50 MHz to 1 GHz, VGIN = 0.7 V, VPOS = 5 V (with L Pad, with No Pad, Normalized to 50 ) AD8348 300 0 2.5 280 -5 2.0 200 1.0 180 (SHUNT RESISTANCE) 160 0.5 140 RETURN LOSS (dB) 1.5 220 -10 SHUNT CAPACITANCE (pF) (SHUNT CAPACITANCE) 240 RETURN LOSS LO INPUT, THROUGH BALUN WITH 60.4 IN SHUNT BETWEEN LOIP/LOIN -15 -20 -25 -30 120 2000 FREQUENCY APPLIED TO LOIP/LOIN (MHz) Figure 43. Input Impedance of Mixer Input vs. FIF, VGIN = 0.7 V, VPOS = 5 V 03678-046 1900 1800 1700 1600 1500 1400 1300 1100 1200 900 1000 800 700 600 500 400 300 100 03678-043 950 1000 900 850 800 750 700 650 600 550 500 450 400 350 300 200 250 150 100 IF FREQUENCY (MHz) 200 -35 0 50 100 Figure 46. Return Loss of LO Input vs. External LO Frequency Through Balun, with Termination Resistor 90 60 120 65 150 30 60 180 SUPPLY CURRENT (mA) MX INPUTS WITH 4:1 BALUN 0 MXIP INPUT PIN 210 330 55 50 VS = 5V VS = 2.7V 45 40 240 03678-044 300 270 Figure 44. S11 of Mixer Input vs. FIF, FIF = 50 MHz to 1 GHz, VGIN = 0.7 V, VPOS = 5 V (With and Without Balun) -5 RETURN LOSS LOIP PIN SINGLE-ENDED, LOIN AC-COUPLED TO GROUND. -15 -20 -25 -30 2000 EXTERNAL LO FREQUENCY (MHz) 03678-045 1900 1800 1700 1600 1500 1400 1300 1200 1100 900 1000 800 700 600 500 400 300 200 -35 100 0 10 20 30 40 TEMPERATURE (C) 50 60 Figure 47. Supply Current vs. Temperature 0 -10 35 -40 -30 -20 -10 Figure 45. Return Loss of LOIP Input vs. External LO Frequency Rev. A | Page 17 of 28 70 80 03678-047 IMPEDANCE CIRCLE RETURN LOSS (dB) SHUNT RESISTANCE () 260 AD8348 THEORY OF OPERATION ENBL 15 VREF IMXO IOFS IAIN IOPP IOPN 14 8 13 6 4 3 BIAS CELL PHASE SPLITTER VREF 5 VCMO 1 LOIP 28 LOIN VCMO DIVIDE BY 2 IFIP 11 PHASE SPLITTER IFIN 10 AD8348 VGIN 17 GAIN CONTROL 19 24 MXIP MXIN ENVG 21 16 23 QXMO QOFS QAIN 25 03678-049 VCMO 18 26 QOPP QOPN Figure 48. Functional Block Diagram VGA The VGA is implemented using the patented X-AMP architecture. The single-ended IF signal is attenuated in eight discrete 6 dB steps by a passive R-2R ladder. Each discrete attenuated version of the IF signal is applied to the input of a transconductance stage. The current outputs of all transconductance stages are summed together and drive a resistive load at the output of the VGA. Gain control is achieved by smoothly turning on and off the relevant transconductance stages with a temperaturecompensated interpolation circuit. This scheme allows the gain to continuously vary over a 44 dB range with linear-in-decibel gain control. This configuration also keeps the relative dynamic range constant (for example, IIP3 - NF in dB) over the gain setting; however, the absolute intermodulation intercepts and noise figure vary directly with gain. The analog voltage VGIN sets the gain. VGIN = 0.2 V is the maximum gain setting, and VGIN = 1.2 V is the minimum voltage gain setting. DOWNCONVERSION MIXERS The output of the VGA drives two (I and Q) double-balanced Gilbert cell downconversion mixers. Alternatively, driving the ENVG pin low can disable the VGA, and the mixers can be externally driven directly via the MXIP and MXIN ports. At the input of the mixer, a degenerated differential pair performs linear voltage-to-current conversions. The differential output current feeds into the mixer core where it is downconverted by the mixing action of the Gilbert cell. The phase splitter provides quadrature LO signals that drive the LO ports of the in-phase and quadrature mixers. Buffers at the output of each mixer drive the IMXO and QMXO pins. These linear, low output impedance buffers drive 40 , temperature-stable, passive resistors in series with each output pin (IMXO and QMXO). This 40 should be considered when calculating the reverse termination if an external filter is inserted between IMXO (QMXO) and IAIN (QAIN). The VCMO pin sets the dc output level of the buffer. This can be set externally or connected to the on-chip 1.0 V reference, VREF. Quadrature generation is achieved using a divide-by-2 frequency divider. Unlike a polyphase filter that achieves quadrature over a limited frequency range, the divide-by-2 approach maintains quadrature over a broad frequency range and does not attenuate the LO. The user, however, must provide an external signal XLO that is twice the frequency of the desired LO frequency. XLO drives the clock inputs of two flip-flops that divide down the frequency by a factor of 2. The outputs of the two flip-flops are one-half period of XLO out of phase. Equivalently, the outputs are onequarter period (90) of the desired LO frequency out of phase. Because the transitions on XLO define the phase difference at the outputs, deviation from 50% duty cycle translates directly to quadrature phase errors. If the user generates XLO from a 1x frequency (fREF) and a frequency-doubling circuit (XLO = 2 x fREF), fundamentally there is a 180 phase uncertainty between fREF and the AD8348 internal quadrature LO. The phase relationship between I and Q LO, however, is always 90. I/Q BASEBAND AMPLIFIERS Two (I and Q) fixed gain (20 dB), single-ended-to-differential amplifiers are provided to amplify the demodulated signal after off-chip filtering. The amplifiers use voltage feedback to linearize the gain over the demodulation bandwidth. These amplifiers can be used to maximize the dynamic range at the input of an ADC following the AD8348. The input to the baseband amplifiers, IAIN (QAIN), feeds into the base of a bipolar transistor with an input impedance of roughly 50 k. The baseband amplifiers sense the single-ended difference between IAIN (QAIN) and VCMO. IAIN (QAIN) can be dc biased by terminating it with a shunt resistor to VCMO, such as when an external filter is inserted between IMXO (QMXO) and IAIN (QAIN). Alternatively, any dc connection to IMXO (QXMO) can provide appropriate bias via the offset-nulling loop. ENABLE A master biasing cell that can be disabled using the ENBL pin controls the biasing for the chip. If the ENBL pin is held low, the entire chip powers down to a low power sleep mode, typically consuming 75 A at 5 V. BASEBAND OFFSET CANCELLATION A low output current integrator senses the output voltage offset at IOPP and IOPN (QOPP and QOPN) and injects a nulling current into the signal path. The integration time constant of the offset-nulling loop is set by Capacitor COFS from IOFS (QOFS) to Rev. A | Page 18 of 28 AD8348 The IOFS (QOFS) pin must be connected to either a bypass capacitor (>0.1 F) or an external voltage source to prevent the feedback loop from oscillating. VCMO. This forms a high-pass response for the baseband signal path with a lower 3 dB frequency of f PASS = 1 2 x 2650 x COFS Alternatively, the user can externally adjust the dc offset by driving IOFS (QOFS) with a digital-to-analog converter or other voltage source. In this case, the baseband circuit operates all the way down to dc (fPASS = 0 Hz). The integrator output current is only 50 A and can be easily overridden with an external voltage source. The nominal voltage level applied to IOFS (QOFS) to produce a 0 V differential offset at the baseband outputs is 900 mV. The feedback loop will be broken at dc if an ac-coupled baseband filter is placed between the mixer outputs and the baseband amplifier inputs. If an ac-coupled filter is implemented, the user must handle the offset compensation via some external means. Rev. A | Page 19 of 28 AD8348 APPLICATIONS LO BASIC CONNECTIONS 4 5 3 1 Figure 49 shows the basic connections schematic for the AD8348. J21 LO ETC1-1-13 4 5 1000pF T21 ETC1-1-13 1000pF 60.4 3 1 R21 60.4 C22 1000pF 1 LOIP LOIN 28 03678-050 C21 1000pF AD8348 C52 0.1F C51 100pF J2I IOPP VREF 3 IOPN QOPN 26 4 IOPP QOPP 25 5 VCMO 6 IAIN R31 57.6 +VS R32 174 C31 1000pF C54 0.1F COM3 22 8 IMXO QMXO 21 C53 100pF C0l 0.1F C11 4.7F 10 IFIN MXIN 19 11 IFIP MXIP 18 12 VPOS2 VGIN 17 13 IOFS QOFS 16 14 VREF ENBL 15 +VS SW12 MX QAIN 23 7 COM3 Alternatively, the LO port can be driven from a single-ended source without a balun (Figure 51). The LO signal is ac-coupled directly into the LOIP pin via an ac-coupling capacitor, and the LOIN pin is ac-coupled to ground. Driving the LO port from a singleended source results in an increase in both quadrature phase error and LO leakage. J2Q QOPP IF ENVG 24 9 COM2 VPOS3 20 C32 1000pF IFIP Figure 50. Differential LO Drive with Balun J3Q QOPN C55 100pF C56 0.1F +VS R42 C43 1000pF 0 MXIP C42 1000pF VGIN C0Q 0.1F LO T41 ETK4-2T C41 1F 1000pF 1000pF 60.4 ENBL +VS SW11 1 03678-064 J3I IOPN LOIN 28 2 VPOS1 COM1 27 DENBL LOIP LOIN 28 03678-051 1 LOIP +VS Figure 49. Basic Connections Schematic Figure 51. Single-Ended LO Drive POWER SUPPLY The voltage supply for the AD8348, between 2.7 V and 5 V, should be provided to the +VPOSx pins, and ground should be connected to the COMx pins. Each supply pin should be decoupled separately using two capacitors whose recommended values are 100 pF and 0.1 F (values close to these can also be used). The recommended LO drive level is between -12 dBm and 0 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 2 GHz. DEVICE ENABLE The IF inputs have an input impedance of 200 . A broadband 50 match can be presented to the driving source through the use of a minimum-loss L pad. This minimum-loss pad introduces an 11.46 dB loss in the input path and must be taken into account when calculating metrics such as gain and noise figure. Figure 42 shows the S11 of the IF input with and without the L pad. VGA ENABLE Driving the voltage on the ENVG pin to VS enables the VGA. In this mode, the MX inputs are disabled and the IF inputs are used. Grounding the ENVG pin disables the VGA and the IF inputs. When the VGA is disabled, the MX inputs should be used. 1000pF 10 IFIN 11 IFIP 57.6 IFIP GAIN CONTROL 174 1000pF When the VGA is enabled, the voltage applied to the VGIN pin sets the gain. The gain control voltage range is between 0.2 V and 1.2 V. This corresponds to a gain range between +25.5 dB and -18.5 dB. LO INPUTS For optimum performance, the local oscillator port should be driven differentially through a balun. The recommended balun is M/A-COM ETC1-1-13. The LO inputs to the device should be ac-coupled, unless an ac-coupled transformer is being used. For a broadband match to a 50 source, a 60.4 resistor should be placed between the LOIP and LION pins. 03678-052 To enable the device, the ENBL pin should be driven to VS. Grounding the ENBL pin disables the device. IF INPUTS Figure 52. Minimum-Loss L Pad for 50 IF Input MX INPUTS The mixer inputs, MXIP and MXIN, have a nominal impedance of 200 and should be driven differentially. When driven from a differential source, the input should be ac-coupled to the source via capacitors, as shown in Figure 53. Rev. A | Page 20 of 28 AD8348 LO 1000pF MXIN 19 4 5 MXIN 1:1 3 1 1000pF +VS If the MX inputs are to be driven from a single-ended 50 source, a 4:1 balun can be used to transform the 200 impedance of the inputs to 50 while performing the required single-endedto-differential conversion. The recommended transformer is the M/A-COM ETK4-2T. 0.1F 100pF TO BASEBAND I ADC VREF 1.02k 1000pF MXIN 19 ETK4-2T MXIP 1000pF 03678-066 1F 1000pF AD8348 Figure 53. Driving the MX Inputs from a Differential Source MXIP 18 60.4 1 LOIP LOIN 28 2 VPOS1 COM1 27 3 IOPN QOPN 26 4 IOPP QOPP 25 5 VCMO ENVG 24 6 IAIN 7 COM3 COM3 22 8 IMXO QMXO 21 Figure 54. Driving the MX Inputs from a Single-Ended 50 Source +VS 9 COM2 VPOS3 20 10 IFIN MXIN 19 11 IFIP MXIP 18 BASEBAND OUTPUTS 100pF 100pF VREF The baseband amplifier outputs, IOPP, IOPN, QOPP, and QOPN, should be presented with loads of at least 2 k (single-ended to ground). They are not designed to drive 50 loads directly. The typical swing for these outputs is 2 V p-p differential (1 V p-p single-ended), but larger swings are possible as long as care is taken to ensure that the signals remain within the lower limit of 0.5 V and the upper limit of VS - 1 V of the output swing. To achieve a larger swing, it is necessary to adjust the common-mode bias of the baseband output signals. Increasing the swing can have the benefit of improving the signal-to-noise ratio of the baseband amplifier output. 1000pF 1.24k 100pF VCMO +VS 0.1F 1000pF 1000pF 1000pF 0.1F +VS QAIN 23 1000pF IF INPUT ZO = 200 TO BASEBAND Q ADC 12 VPOS2 13 IOFS QOFS 16 VGIN 17 14 VREF ENBL 15 1 COMM ACOM 16 2 CHPF 3 DECL VTGT 14 4 INHI VPOS 13 5 INLO VOUT 12 6 DECL VSET 11 7 PWDN ACOM 10 8 COMM 100pF 100pF +VS AD8362 1F VREF 15 1F 1F 100pF 1F 0.1F +VS VSET 1F When connecting the baseband outputs to other devices, care should be taken to ensure that the outputs are not capacitively loaded by approximately 20 pF or more. Such loads could potentially overload the output or induce oscillations. The effect of capacitive loading on the baseband amplifier outputs can be mitigated by inserting series resistors of approximately 200 . OUTPUT DC BIAS LEVEL The dc bias of the mixer outputs and the baseband amplifier inputs and outputs is determined by the voltage that is driven onto the VCMO pin. The range of this voltage is typically between 500 mV and 4 V when operating with a 5 V supply. To achieve maximum voltage swing from the baseband amplifiers, VCMO should be driven at 2.25 V; this allows a swing of up to 7 V p-p differential (3.5 V p-p single-ended). INTERFACING TO DETECTOR FOR AGC OPERATION The AD8348 can be interfaced with a detector such as the AD8362 rms-to-dc converter to provide an automatic signalleveling function for the baseband outputs. CLPF 9 03678-0-055 MXIP 1000pF 03678-053 MXIP 18 Figure 55. AD8362 Configuration for AGC Operation Assuming the I and Q channels have the same rms power, the mixer output (or the output of the baseband filter) of one channel can be used as the input of the AD8362. The AD8362 should be operated in a region where its linearity error is small. Also, a voltage divider should be implemented with an external resistor in series with the 200 input impedance of the AD8362 input. This attenuates the AD8348 mixer output so that the AD8362 input is not overdriven. The size of the resistor between the mixer output and the AD8362 input should be chosen so that the peak signal level at the input of the AD8362 is about 10 dB less than the approximately 10 dBm maximum of the AD8362 dynamic range. The other side of the AD8348 baseband output should be loaded with a resistance equal to the series resistance of the attenuating resistor in series with the AD8362's 200 input impedance. This resistor should be tied to the source driving VCMO so that there is no dc drawn from the mixer output. Rev. A | Page 21 of 28 AD8348 Care should be taken to ensure that blockers--unwanted signals in the band of interest that are demodulated along with the desired signal--do not dominate the rms power of the AD8362 input. This can cause an undesired reduction in the level of the mixer output. To overcome this, baseband filtering can be implemented to filter out undesired signals before the signal is presented to the AD8362. Figure 56 shows the effectiveness of the AGC loop in maintaining a baseband amplifier output amplitude with less than 0.5 dB of amplitude error over an IF input range of 40 dB while demodulating a QPSK-modulated signal at 380 MHz. The AD8362 is insensitive to crest factor variations and therefore provides similar performance regardless of the modulation of the incoming signal. 140 3 -5.1dBm re 10k QPSK 2 The frequency response and group delay of this filter are shown in Figure 58 and Figure 59. 0 -10 -20 -30 -40 -50 -60 120 1 110 0 100 -1 90 -2 -80 10 FREQUENCY (MHz) 1 100 03678-057 ERROR ERROR (dB) -70 Figure 58. Baseband Filter Response 50 -3 -45 -35 -25 -15 -5 IFIP POWER INPUT (dBm, ZO = 200) 5 -4 Figure 56. AD8348 Baseband Amplifier Output vs. IF Input Power with AD8362 AGC Loop BASEBAND FILTERS Baseband low-pass or band-pass filtering can be conveniently performed between the mixer outputs (IMXO and QMXO) and the input to the baseband amplifiers. Consideration should be given to the output impedance of the mixers (40 ). C2 8.2pF L1 0.68H L2 1.2H C5 150pF 30 25 1 20 2 15 10 5 0 1 10 FREQUENCY (MHz) Figure 59. Baseband Filter Group Delay R1 60 IMXO 35 C6 82pF VCMO TO AD8362 INPUT IF AGC LOOP IS USED R2 100 IAIN AD8348 03678-056 C1 4.7pF 40 Figure 57. Baseband Filter Schematic Rev. A | Page 22 of 28 100 03678-058 70 -55 45 GROUP DELAY (ns) 80 03678-065 I CHANNEL VOLTAGE OUTPUT (IOPP - IOPN) (mV rms) 130 Figure 57 shows the schematic for a 100 , fourth-order elliptic low-pass filter with a 3 dB cutoff frequency of 20 MHz. Source and load impedances of approximately 100 ensure that the filter sees a matched source and load. This also ensures that the mixer output is driving an overall load of 200 . Note that the shunt termination resistor is tied to the source driving VCMO and not to ground. This ensures that the input to the baseband amplifier is biased to the proper reference level. VCMO is not an output pin and must be biased by a low impedance source. ATTENUATION (dB) The level of the mixer output (or the output of the baseband filter) can then be set by varying the setpoint voltage fed to Pin 11 (VSET) of the AD8362. AD8348 The device is enabled by moving Switch SW11 (at the bottom left of the evaluation board) to the ENBL position. The device is disabled by moving SW11 to the DENBL position. If desired, the device can be enabled and disabled from an external source that can be fed into the ENBL SMA connector or the VENB test point, in which case SW11 should be placed in the DENBL position. LO GENERATION Analog Devices has a line of PLLs that can be used for generating the LO signal. Table 4 lists the PLLs and their maximum frequency and phase noise performance. Table 4. ADI PLL Selection Table ADI Model ADF4001BRU ADF4001BCP ADF4110BRU ADF4110BCP ADF4111BRU ADF4111BCP ADF4112BRU ADF4112BCP ADF4116BRU ADF4117BRU ADF4118BRU Frequency FIN (MHz) 165 165 550 550 1200 1200 3000 3000 550 1200 3000 @ 1 kHz N dBc/Hz, 200 kHz PFD -99 -99 -91 -91 -78 -78 -86 -86 -89 -87 -90 The IF and MX inputs are selected via SW12. The switch should be moved in the direction of the desired input. Gain Control For convenience, a potentiometer, R15, is provided to allow for changes in gain without the need for an additional dc voltage source. To use the potentiometer, the SW13 switch must be set to the POT position. Alternatively, an external voltage applied to either the test point or SMA connector labeled VGIN can set the gain. SW13 must be set to the EXT position when an external gain control voltage is used. LO Input ADI also offers the ADF4360 fully integrated synthesizer and VCO on a single chip that offers differential outputs for driving the local oscillator input of the AD8348. This means that the user can eliminate the use of a balun for single-ended-to-differential conversions. The ADF4360 comes as a family of chips with six operating frequency ranges. One can be chosen depending on the local oscillator frequency required. Table 5 shows the options available. Table 5. ADF4360 Family Operating Frequencies ADI Model ADF4360-1 ADF4360-2 ADF4360-3 ADF4360-4 ADF4360-5 ADF4360-6 ADF4360-7 Output Frequency Range (MHz) 2150 to 2450 1800 to 2150 1550 to 1950 1400 to 1800 1150 to 1400 1000 to 1250 Lower frequencies set by external L EVALUATION BOARD Figure 60 shows the schematic for the AD8348 evaluation board. Note that uninstalled components are indicated with the OPEN designation. The board is powered by a single supply in the range of 2.7 V to 5.5 V. Table 6 details the various configuration options of the evaluation board. Table 7 shows the various jumper configurations for operating the evaluation board with different signal paths. Power to operate the board can be fed to a single VS test point located near the LO input port at the top of the evaluation board. A GND test point is conveniently provided next to the VS test point for the return path. The local oscillator signal should be fed to the SMA Connector J21. This port is terminated in 50 . The acceptable LO power input range is from -12 dBm to 0 dBm and must be at a frequency double that of the IF/MX frequency. Remember that the AD8348 uses a 2:1 frequency divider in the LO path to generate the internally required quadrature-phase-related LO signals. IF Input The IF input should be fed into the SMA connector IFIP. The VGA must be enabled when this port is used (SW12 in the IF position). When this IF input is chosen, the signal path includes a minimum-loss attenuator to transform a 50 input source to the 200 source impedance level for which the VGA was designed. This pad provides a very broadband input match at the expense of an 11.46 dB power attenuation in the input path. It is very important to take this into account when measuring the noise and distortion performance of the unmodified board using the IFIP input; the apparent noise figure will be degraded by 11.46 dB, and the apparent IIP3 will be 11.46 dB higher than actual. If full weak-signal performance is desired from the evaluation board, the attenuator (comprising R31 and R32) should be removed and replaced with a low-loss RF transformer providing the desired 4:1 impedance ratio. When a transformer is used, IFIN should be ac-coupled to ground and not driven differentially with IFIP. MX Input The evaluation board is by default set for a differential MX drive through a balun (T41) from a single-ended source fed into the MXIP SMA connector. When the MX inputs are used, the internal VGA is bypassed. To change to a differential driving source, T41 should be removed along with Resistor R42. The 0 R43 and R44 resistors should be installed in place of T41 to bridge the gap between the input traces. This presents a nominal Rev. A | Page 23 of 28 AD8348 Baseband Outputs differential impedance of 200 (100 per side). The differential inputs should then be fed into SMA connectors MXIP and MXIN. The baseband outputs are made available at the IOPP, IOPN, QOPP, and QOPN test points and SMA connectors. These outputs are not designed to be connected directly to 50 loads and should be presented with loads of approximately 2 k or greater. Mixer Outputs The I and Q mixer outputs are available through the IMXO and QMXO SMA connectors. These outputs are biased to VCMO and are not designed to drive loads smaller than 200 . To prevent damage to test equipment that cannot tolerate dc biases, pads for series dc-blocking capacitors are provided. These pads are populated with 0 by default. J21 LO C52 0.1F GND T21 ETC1-1-13 IOPN J3I IOPN QOPN 3 1 GND C9I OPEN R5I 0 IOPP C8I OPEN R4I 0 C21 1000pF R21 60.4 C22 1000pF R5Q 0 C9Q OPEN GND R4Q 0 C8Q OPEN QOPP J3Q QOPN AD8348 J2I IOPP VCMO J1I IMXO C10I 0 C13 0.1F LK2I C3I OPEN C7I OPEN LK4I IMXO L3I OPEN C6I OPEN L2I OPEN L1I OPEN C2I OPEN C1I OPEN C5I OPEN C4I OPEN LK1I R1I OPEN R32 174 C31 1000pF +VS C54 0.1F C53 100pF LK5I LOIN 28 VPOS1 COM1 27 3 IOPN +VS QOPN 26 4 IOPP QOPP 25 5 VCMO ENVG 24 R3Q 49.9 ENBL MX VCMO LK4Q IAIN QAIN 23 7 COM3 COM3 22 8 IMXO QMXO 21 9 COM2 VPOS3 20 10 IFIN L1Q OPEN L2Q OPEN L3Q OPEN LK1Q C1Q OPEN C2Q OPEN C3Q OPEN R1Q OPEN IFIP MXIP 18 12 VPOS2 VGIN 17 13 IOFS QOFS 16 14 VREF ENBL 15 C4Q OPEN C55 100pF MXIN 19 11 QMXO LK3Q C5Q OPEN C55 0.1F C6Q OPEN J1Q QMXO C10Q 0 LK2Q C7Q OPEN VREF R44 OPEN R42 C43 1000pF 0 MXIN T41 ETK4-2T MXIP R43 OPEN C42 1000pF DENBL IOFS C11 4.7F POT C0I 0.1F QOFS Figure 60. Evaluation Board Schematic Rev. A | Page 24 of 28 R41 OPEN R14 10k LK5Q SW13 R11 49.9 R2Q OPEN VCMO +VS C41 1F SW11 ENBL IF J2Q QOPP +VS R12 10k VENB 2 6 LK3I C32 1000pF IFIP LOIP LK11 VCMO R31 57.6 1 SW12 R3I 49.9 R2I OPEN 4 5 C51 100pF C0Q 0.1F C12 0.1F EXT R13 OPEN R15 10k POT VGIN 03678-059 +VS The dc bias level of the baseband amplifier outputs are by default tied to VREF through LK11. If desired, the dc bias level can be changed by removing LK11 and driving a dc voltage onto the VCMO test point. 03678-060 AD8348 Rev. A | Page 25 of 28 03678-062 AD8348 03678-063 Figure 63. Evaluation Board Bottom Layer Figure 64. Evaluation Board Bottom Silkscreen Rev. A | Page 26 of 28 AD8348 Table 6. Evaluation Board Configuration Options Component VS, GND SW11, ENBL SW13, R15, VGIN SW12 IFIP, R31, R32 MXIP, MXIN, T41, R41, R42, C42, C43 LK11, VCMO C8, C9, R4, R5 (I and Q) C10 (I and Q) C1 to C7, R1, R2, L1 to L3 (I and Q) LK5 (I and Q) Function Power supply and ground vector pins. Device enable: Place SW11 in the ENBL position to connect the ENBL pin to VS. Place SW11 in the DENBL position to disable the device by grounding the Pin ENBL through a 50 pull-down resistor. The device can also be enabled via an external voltage applied to ENBL or VENB. Gain control selection: With SW13 in the POT position, the gain of the VGA can be set using the R15 potentiometer. With SW13 in the EXT position, the VGA gain can be set by an external voltage to the SMA connector VGIN. For VGA operation, the VGA must first be enabled by setting SW12 to the IF position. VGA enable selection: With SW12 in the IF position, the ENVG pin is connected to VS and the VGA is enabled. The IF input should be used when SW12 is in the IF position. With SW12 in the MX position, the ENVG pin is grounded and the VGA is disabled. The MX inputs should be used when SW12 is in the MX position. IF inputs: The single-ended IF signal should be connected to this SMA connector. R31 and R32 form an L pad that presents a 50 termination to the driving source. This L pad introduces an 11.46 dB loss in the input signal path and should be taken into consideration when calculating the gain of the AD8348. Mixer inputs: These inputs can be configured for either differential or single-ended operation. The evaluation board is by default set for differential MX drive through a balun (T41) from a single-ended source fed into the MXIP SMA connector. To change to a differential driving source, T41 should be removed along with Resistor R42. The 0 Resistors R43 and R44 should be installed in place of T41 to bridge the gap between the input traces. This will present a nominal differential impedance of 200 (100 per side). The differential inputs should then be fed into SMA connectors MXIP and MXIN. Baseband amplifier output bias: Installing LK11 connects VREF to VCMO. This sets the bias level on the baseband amplifiers to VREF, which is equal to approximately 1 V. Alternatively, with LK11 removed, the bias level of the baseband amplifiers can be set by applying an external voltage to the VCMO test point. Baseband amplifier outputs and output filter: Additional low-pass filtering can be provided at the baseband output with these filters. Mixer output dc-blocking capacitors: The mixer outputs are biased to VCMO. To prevent damage to test equipment that cannot tolerate dc biases, C10 is provided to block the dc component, thus protecting the test equipment. Baseband filter: These components are provided for baseband filtering between the mixer outputs and the baseband amplifier inputs. The baseband amplifier input impedance is high and the filter termination impedance is set by R2. See Table 7 for the jumper settings. Default Condition Not applicable SW11 = ENBL Offset compensation loop disable: Installing these jumpers will disable the offset compensation loop for the corresponding channel. LK5x = OPEN SW13 = POT SW12 = IF R31 = 57.6 R32 = 174 T41 = M/A-COM ETK4-2T; R41= OPEN; C42, C43 = 1000 pF; R42 = 0 LK11 installed R4, R5 = 0 C10 = 0 All = OPEN Table 7. Filter-Jumper Configuration Options Condition xMXO to xAIN Directly xMXO to xAIN via Filter xMXO to J1x Directly, xAIN Unused xMXO to J1x via Filter, xAIN Unused Drive xAIN from J1x LK1x LK2x LK3x * * * * * * Rev. A | Page 27 of 28 LK4x * * * AD8348 OUTLINE DIMENSIONS 9.80 9.70 9.60 28 15 4.50 4.40 4.30 1 6.40 BSC 14 PIN 1 0.65 BSC 0.15 0.05 COPLANARITY 0.10 0.30 0.19 1.20 MAX SEATING PLANE 0.20 0.09 8 0 0.75 0.60 0.45 COMPLIANT TO JEDEC STANDARDS MO-153AE Figure 65. 28-Lead Thin Shrink Small Outline Package [TSSOP] (RU-28) Dimensions shown in millimeters ORDERING GUIDE Model AD8348ARU AD8348ARU-REEL7 AD8348ARUZ 1 AD8348ARUZ-REEL71 AD8348-EVAL 1 Temperature Range -40C to +85C -40C to +85C -40C to +85C -40C to +85C Package Description 28-Lead Thin Shrink Small Outline Package [TSSOP] 28-Lead Thin Shrink Small Outline Package [TSSOP] 7" Tape and Reel 28-Lead Thin Shrink Small Outline Package [TSSOP] 28-Lead Thin Shrink Small Outline Package [TSSOP] 7" Tape and Reel Evaluation Board Z = Pb-free part. (c)2006 Analog Devices, Inc. All rights reserved. Trademarks and registered trademarks are the property of their respective owners. C03678-0-4/06(A) Rev. A | Page 28 of 28 Package Option RU-28 RU-28 RU-28 RU-28