VCA2612Y

® VCA VCA2612 261 2 For most current data sheet and other product information, visit www.burr-brown.com Dual, VARIABLE GAIN AMPLIFIER with Low Noise Preamp TM FEATURES q LOW NOISE PREAMP: • Low Input Noise: 1.25nV/√Hz • Active Termination Noise Reduction • Switchable Termination Value • 80MHz Bandwidth • 5dB to 25dB Gain • Differential Input /Output q LOW NOISE VARIABLE GAIN AMPLIFIER: • Low Noise VCA: 3.3nV/√Hz, Differential Programming Optimizes Noise Figure • 24dB to 45dB Gain • 40MHz Bandwidth • Differential Input /Output q LOW CROSSTALK: 52dB at Max Gain, 5MHz q HIGH-SPEED VARIABLE GAIN ADJUST q SWITCHABLE EXTERNAL PROCESSING DESCRIPTION The VCA2612 is a highly integrated, dual receive channel, signal processing subsystem. Each channel of the product consists of a low noise pre-amplifier (LNP) and a Variable Gain Amplifier (VGA). The LNP circuit provides the necessary connections to implement Active Termination (AT), a method of cable termination which results in up to 4.6dB noise figure improvement. Different cable termination characteristics can be accommodated by utilizing the VCA2612’s switchable LNA feedback pins. The LNP has the ability to accept both differential and single ended inputs, and generates a differential output signal. The LNP provides strappable gains of 5dB, 17dB, 22dB and 25dB. The output of the LNP can be accessed externally for further signal processing, or fed directly into the VGA. The VCA2612’s VGA section consists of two parts, the Voltage Controlled Attenuator (VCA) and the Programmable Gain Amplifier (PGA). The gain and gain range of the Programmable Gain Amplifier can be digitally programmed. The combination of these two programmable elements results in a variable gain ranging from 0dB up to a maximum gain as defined by the user through external connections. The output of the VGA can be used in either a single-ended or differential mode to drive high performance analog-to-digital converters. The VCA2612 also features low crosstalk and outstanding distortion performance. The combination of low noise, and gain range programmability make the VCA2612 a versatile building block in a number of applications where noise performance is critical. The VCA2612 is available in a TQFP-48 package. Maximum Gain Select FBCNTL RF2 RF1 LNPOUTN VCAINN VCACNTL MGS1 MGS2 MGS3 FBSW FB VCA2612 (1 of 2 Channels) APPLICATIONS q ULTRASOUND SYSTEMS q WIRELESS RECEIVERS q TEST EQUIPMENT Analog Control Maximum Gain Select Input LNPINP LNPGS1 LNPGS2 LNPGS3 LNPINN Programmable Gain Amplifier 24 to 45dB VCAOUTN Low Noise Preamp 5dB to 25dB Voltage Controlled Attenuator LNP Gain Set VCAOUTP LNPOUTP VCAINP SEL International Airport Industrial Park • Mailing Address: PO Box 11400, Tucson, AZ 85734 • Street Address: 6730 S. Tucson Blvd., Tucson, AZ 85706 • Tel: (520) 746-1111 Twx: 910-952-1111 • Internet: http://www.burr-brown.com/ • Cable: BBRCORP • Telex: 066-6491 • FAX: (520) 889-1510 • Immediate Product Info: (800) 548-6132 ® © 2000 Burr-Brown Corporation PDS-1541B 1 Printed in U.S.A. VCA2612 March, 2000 SPECIFICATIONS At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. VCA2612Y PARAMETER PREAMPLIFIER Input Resistance Input Capacitance Input Bias Current CMRR Maximum Input Voltage Input Voltage Noise(1) Input Current Noise Noise Figure, RS = 75Ω, RIN = 75Ω(1) Bandwidth CONDITIONS MIN TYP MAX UNITS kΩ pF nA dB Vp-p mVp-p nV/√Hz nV/√Hz fA/√Hz dB MHz Vp-p MHz V/µs V Ω mA dBc dBc dBc dBc Vp-p dB ns dB/V dB mV V MΩ µs 5.25 475 V mW f = 1MHz, VCACNTL = 0.2V Preamp Gain = +5dB Preamp Gain = +25dB Preamp Gain = +5dB Preamp Gain = +25dB Independent of Gain RF = 550Ω, PreAmp Gain = 22dB, PGA Gain = 39dB Gain = 22dB 600 15 1 50 1 112 3.5 1.25 350 6.2 80 2 40 300 2.5 ±1 1 ±40 –71 –63 –80 –80 6 68 ±2 10.9 ±50 0 to 3.0 1 0.2 4.75 5.0 410 ±1(2) PROGRAMMABLE VARIABLE GAIN AMPLIFIER Peak Input Voltage Differential –3dB Bandwidth Slew Rate Output Signal Range RL ≥ 500Ω Each Side to Ground Output Impedance f = 5MHz Output Short-Circuit Current Third Harmonic Distortion f = 5MHz, VOUT = 1Vp-p, VCACNTL = 3.0V Second Harmonic Distortion f = 5MHz, VOUT = 1Vp-p, VCACNTL = 3.0V IMD, Two-Tone VOUT = 2Vp-p, f = 1MHz VOUT = 2Vp-p, f = 10MHz 1dB Compression Point f = 5MHz, Output Referred, Differential VOUT = 1Vp-p, f = 1MHz, Max Gain Both Channels Crosstalk Group Delay Variation 1MHz < f < 10MHz, Full Gain Range ACCURACY Gain Slope Gain Error Output Offset Voltage GAIN CONTROL INTERFACE Input Voltage (VCACNTL) Range Input Resistance Response Time POWER SUPPLY Specified Operating Range Power Dissipation –45 –45 45dB Gain Change, MGS = 111 Operating, Both Channels NOTE: (1) For preamp driving VGA. (2) Referenced to best fit dB-linear curve. The information provided herein is believed to be reliable; however, BURR-BROWN assumes no responsibility for inaccuracies or omissions. BURR-BROWN assumes no responsibility for the use of this information, and all use of such information shall be entirely at the user’s own risk. Prices and specifications are subject to change without notice. No patent rights or licenses to any of the circuits described herein are implied or granted to any third party. BURR-BROWN does not authorize or warrant any BURR-BROWN product for use in life support devices and/or systems. ® VCA2612 2 ELECTROSTATIC DISCHARGE SENSITIVITY This integrated circuit can be damaged by ESD. Burr-Brown recommends that all integrated circuits be handled with appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications. PACKAGE/ORDERING INFORMATION PACKAGE DRAWING NUMBER 355 ABSOLUTE MAXIMUM RATINGS Power Supply (+VS) ............................................................................. +6V Analog Input ............................................................. –0.3V to (+VS + 0.3V) Logic Input ............................................................... –0.3V to (+VS + 0.3V) Case Temperature ......................................................................... +100°C Junction Temperature .................................................................... +150°C Storage Temperature ...................................................... –40°C to +150°C PRODUCT VCA2612Y PACKAGE TQFP-48 Surface Mount SPECIFIED TEMPERATURE RANGE –40°C to +85°C PACKAGE MARKING A12 ORDERING NUMBER(1) VCA2612Y/250 VCA2612Y/2K TRANSPORT MEDIA Tape and Reel " " " " " " NOTE: (1) Models with a slash (/) are available only in Tape and Reel in the quantities indicated (e.g., /2K indicates 2000 devices per reel). Ordering 2000 pieces of “VCA2612Y/2K” will get a single 2000-piece Tape and Reel. ® 3 VCA2612 PIN CONFIGURATION VCAOUTNA VCACNTL VCAOUTPB VCAINSEL VCAOUTNB 38 VCAOUTPA FBSWCNTL GNDA MGS1 MGS2 48 VDDA NC NC VCAINNA VCAINPA LNPOUTNA LNPOUTPA SWFBA FBA 1 2 3 4 5 6 7 8 9 47 46 45 44 43 42 41 40 MGS3 39 37 36 VDDB 35 NC 34 NC 33 VCAINNB 32 VCAINPB GNDB 31 LNPOUTNB 30 LNPOUTPB 29 SWFBB 28 FBB 27 COMP1B 26 COMP2B 25 LNPINNB 24 VCA2612 COMP1A 10 COMP2A 11 LNPINNA 12 13 14 15 16 17 18 19 20 21 22 23 LNPINPA GNDR VDDR VBIAS VCM LNPGS3A LNPGS2A LNPGS1A LNPINPB LNPGS1B LNPGS2B PIN DESCRIPTIONS PIN 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 DESIGNATOR VDDA NC NC VCAINNA VCAINPA LNPOUTNA LNPOUTPA SWFBA FBA COMP1A COMP2A LNPINNA LNPGS3A LNPGS2A LNPGS1A LNPINPA VDDR VBIAS VCM GNDR LNPINPB LNPGS1B LNPGS2B LNPGS3B DESCRIPTION Channel A +Supply Do Not Connect Do Not Connect Channel A VCA Negative Input Channel A VCA Positive Input Channel A LNP Negative Output Channel A LNP Positive Output Channel A Switched Feedback Output Channel A Feedback Output Channel A Frequency Compensation 1 Channel A Frequency Compensation 2 Channel A LNP Inverting Input Channel A LNP Gain Strap 3 Channel A LNP Gain Strap 2 Channel A LNP Gain Strap 1 Channel A LNP Noninverting Input +Supply for Internal Reference 0.01µF Bypass to Ground 0.01µF Bypass to Ground Ground for Internal Reference Channel B LNP Noninverting Input Channel B LNP Gain Strap 1 Channel B LNP Gain Strap 2 Channel B LNP Gain Strap 3 PIN 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 DESIGNATOR LNPINNB COMP2B COMP1B FBB SWFBB LNPOUTPB LNPOUTNB VCAINPB VCAINNB NC NC VDDB GNDB VCAOUTNB VCAOUTPB MGS3 MGS2 MGS1 VCACNTL VCAINSEL FBSWCNTL VCAOUTPA VCAOUTNA GNDA DESCRIPTION Channel B LNP Inverting Input Channel B Frequency Compensation 2 Channel B Frequency Compensation 1 Channel B Feedback Output Channel B Switched Feedback Output Channel B LNP Positive Output Channel B LNP Negative Output Channel B VCA Positive Input Channel B VCA Negative Input Do Not Connect Do Not Connect Channel B +Analog Supply Channel B Analog Ground Channel B VCA Negative Output Channel B VCA Positive Output Maximum Gain Select 3 (LSB) Maximum Gain Select 2 Maximum Gain Select 1 (MSB) VCA Control Voltage VCA Input Select, HI = External Feedback Switch Control: HI = ON, Channel A VCA Positive Output Channel A VCA Negative Output Channel A Analog Ground ® VCA2612 4 LNPGS3B TYPICAL PERFORMANCE CURVES At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. 65 60 55 50 Gain (dB) GAIN vs VCACNTL MGS = 111 MGS = 110 MGS = 101 Gain Error (dB) GAIN ERROR vs TEMPERATURE 2.0 1.5 1.0 0.5 0 –0.5 –1.0 –1.5 –2.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) +85°C –40°C +25°C 45 40 35 30 25 20 15 MGS = 001 MGS = 000 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) MGS = 011 MGS = 010 MGS = 100 GAIN ERROR vs VCACNTL 2.0 1.5 1.0 1MHz GAIN ERROR vs VCACNTL 2.0 1.5 1.0 Gain Error (dB) Gain Error (dB) 0.5 0 –0.5 10MHz MGS = 000 MGS = 011 0.5 0 –0.5 –1.0 MGS = 111 –1.5 –2.0 5MHz –1.0 –1.5 –2.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) GAIN MATCH: CHA to CHB = 0.2V 100 90 80 70 60 Units Units GAIN MATCH: CHA to CHB = 3.0V 100 90 80 70 60 50 40 30 20 10 0 50 40 30 20 10 0 –0.5 –0.4 –0.3 –0.2 –0.1 0.0 0.1 0.2 0.3 0.4 0.5 –0.5 –0.4 –0.3 –0.2 –0.1 0.0 0.1 0.2 0.3 0.4 0.5 Delta Gain (dB) Delta Gain (dB) ® 5 VCA2612 TYPICAL PERFORMANCE CURVES (Cont.) At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. GAIN vs FREQUENCY (Pre-Amp) 30 25 20 Gain (dB) GAIN vs FREQUENCY (VCA and PGA, VCACNTL = 0.2V) 5.0 LNP = 25dB LNP = 22dB 4.0 3.0 2.0 Gain (dB) 1.0 0.0 –1.0 –2.0 –3.0 MGS = 111 MGS = 100 MGS = 011 MGS = 000 15 LNP = 17dB 10 5 0 LNP = 5dB 0.1 1 Frequency (MHz) 10 100 –4.0 –5.0 0.1 1 Frequency (MHz) 10 100 GAIN vs FREQUENCY (VCA and PGA, VCACNTL = 3.0V) 45 40 35 30 Gain (dB) GAIN vs FREQUENCY (VCACNTL = 3.0V) 60 LNP = 25dB LNP = 22dB MGS = 111 50 MGS = 100 40 Gain (dB) LNP = 17dB 25 20 15 10 5 0 0.1 1 Frequency (MHz) 10 100 MGS = 000 MGS = 011 30 LNP = 5dB 20 10 0 0.1 1 Frequency (MHz) 10 100 GAIN vs FREQUENCY (LNP = 22dB) 60 VCACNTL = 3.0V 50 40 Gain (dB) OUTPUT REFERRED NOISE vs VCACNTL 1800 1600 1400 Noise (nv/√Hz) RS= 50Ω MGS = 111 VCACNTL = 1.6V 1200 1000 800 600 MGS = 011 400 30 20 10 VCACNTL = 0.2V 0 0.1 1 Frequency (MHz) 10 100 200 0 0 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) ® VCA2612 6 TYPICAL PERFORMANCE CURVES (Cont.) At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. 24 22 20 18 16 14 12 10 8 6 4 2 0 INPUT REFERRED NOISE vs VCACNTL 10.0 INPUT REFERRED NOISE vs RS RS= 50Ω MGS = 111 Noise (nV√Hz Noise (nV/√Hz) 1.0 MGS = 011 0.1 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) 1 10 RS (Ω) 100 1000 NOISE FIGURE vs RS (VCACNTL = 3.0V) 11 10 9 Noise Figure (dB) 30 25 Noise Figure (dB) NOISE FIGURE vs VCACNTL 8 7 6 5 4 3 2 1 0 10 100 RS (Ω) 1000 20 15 10 5 0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) LNP vs FREQUENCY (Differential, 2Vp-p) –45 –50 Harmonic Distortion (dBc) LNP vs FREQUENCY (Single-Ended, 1Vp-p) –45 –50 Harmonic Distortion (dBc) –55 3rd Harmonic –60 –65 –70 –75 2nd Harmonic –80 0.1 1 Frequency (MHz) 10 100 –55 2nd Harmonic –60 –65 –70 –75 –80 0.1 1 Frequency (MHz) 10 100 3rd Harmonic ® 7 VCA2612 TYPICAL PERFORMANCE CURVES (Cont.) At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. HARMONIC DISTORTION vs FREQUENCY (Differential, 2Vp-p, MGS = 000) –40 –45 Harmonic Distortion (dBc) HARMONIC DISTORTION vs FREQUENCY (Differential, 2Vp-p, MGS = 011) –40 –45 Harmonic Distortion (dBc) –50 –55 –60 –65 –70 –75 –80 –85 –90 0.1 1 Frequency (MHz) VCACNTL = 0.2V, H2 VCACNTL = 0.2V, H3 VCACNTL = 3.0V, H2 VCACNTL = 3.0V, H3 –50 –55 –60 –65 –70 –75 –80 –85 –90 VCACNTL = 0.2V, H2 VCACNTL = 0.2V, H3 VCACNTL = 3.0V, H2 VCACNTL = 3.0V, H3 10 0.1 1 Frequency (Hz) 10 HARMONIC DISTORTION vs FREQUENCY (Differential, 2Vp-p, MGS = 111) –30 –35 VCACNTL = 0.2V, H2 VCACNTL = 0.2V, H3 VCACNTL = 3.0V, H2 VCACNTL = 3.0V, H3 –40 –45 HARMONIC DISTORTION vs FREQUENCY (Single-Ended, 1Vp-p, MGS = 000) VCACNTL = 0.2V, H2 VCACNTL = 0.2V, H3 VCACNTL = 3.0V, H2 VCACNTL = 3.0V, H3 Harmonic Distortion (dBc) –45 –50 –55 –60 –65 –70 –75 –80 0.1 Harmonic Distortion (dBc) 1 10 –40 –50 –55 –60 –65 –70 –75 –80 –85 –90 0.1 1 Frequency (MHz) 10 Frequency (MHz) HARMONIC DISTORTION vs FREQUENCY (Single-Ended, 1Vp-p, MGS = 011) –40 –45 Harmonic Distortion (dBc) HARMONIC DISTORTION vs FREQUENCY (Single-Ended, 1Vp-p, MGS = 111) –30 –35 –40 –45 –50 –55 –60 –65 –70 –75 –80 –85 VCACNTL = 0.2V, H2 VCACNTL = 0.2V, H3 VCACNTL = 3.0V, H2 VCACNTL = 3.0V, H3 –55 –60 –65 –70 –75 –80 –85 –90 0.1 1 Frequency (MHz) 10 Harmonic Distortion (dBc) –50 VCACNTL = 0.2V, H2 VCACNTL = 0.2V, H3 VCACNTL = 3.0V, H2 VCACNTL = 3.0V, H3 0.1 1 Frequency (MHz) 10 ® VCA2612 8 TYPICAL PERFORMANCE CURVES (Cont.) At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. HARMONIC DISTORTION vs VCACNTL (Differential, 2Vp-p) –45 –50 Harmonic Distortion (dBc) HARMONIC DISTORTION vs VCACNTL (Single-Ended, 1Vp-p) –45 MGS = 000, H2 MGS = 011, H2 MGS = 111, H2 MGS = 000, H3 MGS = 011, H3 MGS = 111, H3 –55 –60 –65 –70 –75 –80 Harmonic Distortion (dBc) MGS = 000, H2 MGS = 011, H2 MGS = 111, H2 MGS = 000, H3 MGS = 011, H3 MGS = 111, H3 –50 –55 –60 –65 –70 –75 –80 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) INTERMODULATION DISTORTION (Differential, 2Vp-p, f = 10MHz) –5 –15 –25 INTERMODULATION DISTORTION (Single-Ended, 1Vp-p, f = 10MHz) –5 –15 –25 –35 Power (dBm) –35 Power (dBm) –45 –55 –65 –75 –85 –95 –105 9.96 9.98 10 Frequency (MHz) 10.2 10.4 –45 –55 –65 –75 –85 –95 –105 9.96 9.98 10 Frequency (MHz) 10.2 10.4 0 –5 –10 –1dB COMPRESSION vs VCACNTL 0 –5 –10 –15 IP3 (dBm) 3rd-ORDER INTERCEPT vs VCACNTL PIN (dBm) –15 –20 –25 –30 –35 –40 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) –20 –25 –30 –35 –40 –45 –50 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4 2.6 2.8 3.0 VCACNTL (V) ® 9 VCA2612 TYPICAL PERFORMANCE CURVES (Cont.) At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. PULSE RESPONSE (BURSTS) (Differential, VCACNTL = 3.0V, MGS = 111) Output 500mV/div OVERLOAD RECOVERY (Differential, VCACNTL = 3.0V, MGS = 111) Output 1V/div Input 10V/div Input 1V/div 200ns/div 200ns/div GAIN RESPONSE (Differential, VCACNTL Pulsed, MGS = 111) Output 500mV/div Cross Talk (dB) CROSS TALK vs FREQUENCY (Single-Ended, 1Vp-p, MGS = 011) 0 –10 –20 –30 –40 –50 –60 –70 –80 –90 VCACNTRL = 3.0V VCACNTRL = 0V VCACNTRL = 1.5V Input 2V/div 100ns/div 0.1 1 Frequency (MHz) 10 CMRR vs FREQUENCY (VCA only) 0 –10 –20 CMRR (dB) CMRR vs FREQUENCY (LNP only) 0 –10 –20 –40 –50 –60 –70 –80 –90 0.1 1 VCACNTL = 1.4V CMRR (dB) 10 100 –30 VCACNTL = 0.2V –30 –40 –50 –60 –70 VCACNTL = 3.0V –80 0.1 1 Frequency (MHz) 10 100 Frequency (MHz) ® VCA2612 10 TYPICAL PERFORMANCE CURVES (Cont.) At TA = +25°C, VDD = 5V, load resistance = 500Ω on each output to ground, MGS = 011, LNP = 22dB and fIN = 5MHz, unless otherwise noted. The input to the preamp (LNP) is single-ended, and the output from the VCA is single-ended unless otherwise noted. 80 79.5 79 ICC vs TEMPERATURE GROUP DELAY vs FREQUENCY 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 1 VCACNTL = 3.0V ICC (mA) 78.5 78 77.5 77 76.5 76 –40 –25 –10 5 20 35 50 65 80 95 Temperature (°C) Group Delay (ns) VCACNTL = 0.2V 10 Frequency (MHz) 100 PSRR vs FREQUENCY –45 –40 –35 –30 –25 –20 –15 –10 –5 0 5 10 1.E+01 1.E+02 1.E+03 1.E+04 1.E+05 1.E+06 1.E+07 PSRR (dB) Frequency (Hz) ® 11 VCA2612 THEORY OF OPERATION The VCA2612 is a dual-channel system consisting of three primary blocks: a Low Noise Preamplifier (LNP), a Voltage Controlled Attenuator (VCA) and a Programmable Gain Amplifier (PGA). For greater system flexibility, an onboard multiplexer is provided for the VCA inputs, selecting either the LNP outputs or external signal inputs. Figure 1 shows a simplified block diagram of the dual channel system. op amp. The “VCM” node shown in the drawing is the VCM output (pin 19). Typical R and C values are shown, yielding a high-pass time constant similar to that of the LNP. If a different common-mode referencing method is used, it is important that the common-mode level be within 10mV of the VCM output for proper operation. 1kΩ External InA Channel A Input Channel A Output Input Signal VCA PGA 47nF To VCA LNP 1kΩ VCM VCA Control Analog Control Maximum Gain Select MGS FIGURE 2. Recommended Signal Coupling. Channel B Output Channel B Input LNP External InB VCA PGA VCA—OVERVIEW The magnitude of the differential VCA input signal (from the LNP or an external source) is reduced by a programmable attenuation factor, set by the analog VCA Control Voltage (VCACNTL) at pin 43. The maximum attenuation factor is further programmable by using the three MGS bits (pins 40-42). Figure 3 illustrates this dual-adjustable characteristic. Internally, the signal is attenuated by having the analog VCACNTL vary the channel resistance of a set of shunt-connected FET transistors. The MGS bits effectively adjust the overall size of the shunt FET by switching parallel components in or out under logic control. At any given maximum gain setting, the analog variable gain characteristic is linear in dB as a function of the control voltage, and is created as a piecewise approximation of an ideal dB-linear transfer function. The VCA gain control circuitry is common to both channels of the VCA2612. FIGURE 1. Simplified Block Diagram of the VCA2612. LNP—OVERVIEW The LNP input may be connected to provide active-feedback signal termination, achieving lower system noise performance than conventional passive shunt termination. Even lower noise performance is obtained if signal termination is not required. The unterminated LNP input impedance is 600kΩ. The LNP can process fully differential or singleended signals in each channel. Differential signal processing results in significantly reduced 2nd-harmonic distortion and improved rejection of common-mode and power supply noise. The first gain stage of the LNP is AC coupled into its output buffer with a 44µs time constant (3.6kHz high-pass characteristic). The buffered LNP outputs are designed to drive the succeeding VCA directly or, if desired, external loads as low as 135Ω with minimal impact on signal distortion. The LNP employs very low impedance local feedback to achieve stable gain with the lowest possible noise and distortion. Four pin-programmable gain settings are available: 5dB, 17dB, 22dB and 25dB. Additional intermediate gains can be programmed by adding trim resistors between the Gain Strap programming pins. The common-mode DC level at the LNP output is nominally 2.5V, matching the input common-mode requirement of the VCA for simple direct coupling. When external signals are fed to the VCA, they should also be set up with a 2.5VDC common-mode level. Figure 2 shows a circuit that demonstrates the recommended coupling method using an external 0 VCA Attenuation (dB) Maximum Attenuation –24 –45 Maximum Attenuation Control Voltage FIGURE 3. Swept Attenuator Characteristic. ® VCA2612 12 PGA OVERVIEW AND OVERALL DEVICE CHARACTERISTICS The differential output of the VCA attenuator is then amplified by the PGA circuit block. This post-amplifier is programmed by the same MGS bits that control the VCA attenuator, yielding an overall swept-gain amplifier characteristic in which the VCA • PGA gain varies from 0dB (unity) to a programmable peak gain of (24, 27, 30, 33, 36, 39. 42, 45) dB. The “GAIN vs VCACNTL” curve on page 5 shows the composite gain control characteristic of the entire VCA2612. Setting VCACNTL to 3.0V causes the digital MGS gain control to step in 3dB increments. Setting VCACNTL to 0V causes all the MGS-controlled gain curves to converge at one point. The gain at the convergence point is the LNP gain less 6dB, because the measurement setup looks at only one side of the differential PGA output, resulting in 6dB lower signal amplitude. ADDITIONAL FEATURES—OVERVIEW Overload protection stages are placed between the attenuator and the PGA, providing a symmetrically clipped output whenever the input becomes large enough to overload the PGA. A comparator senses the overload signal amplitude and substitutes a fixed DC level to prevent undesirable overload recovery effects. As with the previous stages, the VCA is AC coupled into the PGA. In this case, the coupling time constant varies from 5µs at the highest gain (46dB) to 59µs at the lowest gain (25dB). The VCA2612 includes a built-in reference, common to both channels, to supply a regulated voltage for critical areas of the circuit. This reduces the susceptibility to power supply variation, ripple and noise. In addition, separate power supply and ground connections are provided for each channel and for the reference circuitry, further reducing interchannel cross-talk. Further details regarding the design, operation and use of each circuit block are provided in the following sections. LOW NOISE PREAMPLIFIER (LNP)—DETAIL The LNP is designed to achieve a low noise figure, especially when employing active termination. Figure 4 is a simplified schematic of the LNP, illustrating the differential input and output capability. The input stage employs low resistance local feedback to achieve stable low noise, low distortion performance with very high input impedance. Normally, low noise circuits exhibit high power consumption due to the large bias currents required in both input and output stages. The LNP uses a patented technique that combines the input and output stages such that they share the same bias current. Transistors Q4 and Q5 amplify the signal at the gate-source input of Q4, the +IN side of the LNP. The signal is further amplified by the Q1 and Q2 stage, and then by the final Q3 and RL gain stage, which uses the same bias current as the input devices Q4 and Q5. Devices Q6 through Q10 play the same role for signals on the –IN side. The differential gain of the LNP is given in Equation (1): R  Gain = 2 •  L   RS  (1) VDD Q2 RL 93Ω –Out Buffer Q3 RS1 105Ω RS2 34Ω LNPGS2 RS3 17Ω +Out Buffer RL 93Ω Q9 To Bias Circuitry Q8 +IN Q4 LNPGS1 Q7 –IN Q1 LNPGS3 Q10 Q5 Q6 To Bias Circuitry FIGURE 4. Schematic of the Low Noise Pre-Amplifier (LNP). ® 13 VCA2612 where RL is the load resistor in the drains of Q3 and Q8, and RS is the resistor connected between the sources of the input transistors Q4 and Q7. The connections for various RS combinations are brought out to device pins LNPGS1, LNPGS2 and LNPGS3 (pins 13-15 for channel A, 22-24 for channel B). These Gain Strap pins allow the user to establish one of four fixed LNP gain options as shown in Table I. To preserve the low noise performance of the LNP, the user should take care to minimize resistance in the input lead. A parasitic resistance of only 10Ω will contribute 0.4nV/√Hz. NOISE (nv/√ Hz) LNP GAIN (dB) 25 22 17 5 Input-Referred 1.54 1.59 1.82 4.07 Output-Referred 2260 1650 1060 597 LNP PIN STRAPPING LNPGS1, LNPGS2, LNPGS3 Connected Together LNPGS1 Connected to LNPGS3 LNPGS1 Connected to LNPGS2 All Pins Open LNP GAIN (dB) 25 22 17 5 TABLE II. Noise Performance for MGS = 111 and VCACNTL = 3.0V. The LNP is capable of generating a 2Vp-p differential signal. The maximum signal at the LNP input is therefore 2Vp-p divided by the LNP gain. An input signal greater than this would exceed the linear range of the LNP, an especially important consideration at low LNP gain settings. ACTIVE FEEDBACK WITH THE LNP One of the key features of the LNP architecture is the ability to employ active-feedback termination to achieve superior noise performance. Active feedback termination achieves a lower noise figure than conventional shunt termination, essentially because no signal current is wasted in the termination resistor itself. Another way to understand this is as follows: Consider first that the input source, at the far end of the signal cable has a cable-matching source resistance of RS. Using conventional shunt termination at the LNP input, a second terminating resistor of value RS is connected to ground. Therefore, the signal loss is 6dB due to the voltage divider action of the series and shunt RS resistors. The effective source resistance has been reduced by the same factor of 2, but the noise contribution has been reduced by only the √2, only a 3dB reduction. Therefore, the net theoretical SNR degradation is 3dB, assuming a noise-free amplifier input. (In practice, the amplifier noise contribution will degrade both the unterminated and the terminated noise figures, somewhat reducing the distinction between them.) Figure 5 shows an amplifier using active feedback. This diagram appears very similar to a traditional inverting amplifier. However, the analysis is somewhat different because the gain “A” in this case is not a very large open-loop op amp gain; rather it is the relatively low and controlled gain of the LNP itself. Thus, the impedance at the inverting amplifier terminal will be reduced by a finite amount, as given in the familiar relationship of Equation (3): R IN = RF (1 + A) TABLE I. Pin Strappings of the LNP for Various Gains. It is also possible to create other gain settings by connecting an external resistor between LNPGS1 on one side, and LNPGS2 and/or LNPGS3 on the other. In that case, the internal resistor values shown in Figure 4 should be combined with the external resistor to calculate the effective value of RS for use in Equation (1). The resulting expression for external resistor value is given in Equation (2). R EXT = 2 R S1R L + 2 R FIX R L – Gain • R S1R FIX Gain • R S1 – 2 R L (2) where REXT is the externally selected resistor value needed to achieve the desired gain setting, RS1 is the fixed parallel resistor in Figure 4, and RFIX is the effective fixed value of the remaining internal resistors: RS2, RS3 or (RS2 || RS3) depending on the pin connections. Note that the best process and temperature stability will be achieved by using the pre-programmed fixed gain options of Table I, since the gain is then set entirely by internal resistor ratios, which are typically accurate to ±0.5%, and track quite well over process and temperature. When combining external resistors with the internal values to create an effective RS value, note that the internal resistors have a typical temperature coefficient of +700ppm/°C and an absolute value tolerance of approximately ±5%, yielding somewhat less predictable and stable gain settings. With or without external resistors, the board layout should use short Gain Strap connections to minimize parasitic resistance and inductance effects. The overall noise performance of the VCA2612 will vary as a function of gain. Table II shows the typical input-and output-referred noise densities of the entire VCA2612 for maximum VCA and PGA gain; i.e., VCACNTL set to 3.0V and all MGS bits set to “1”. Note that the input-referred noise values include the contribution of a 50Ω fixed source impedance, and are therefore somewhat larger than the intrinsic input noise. As the LNP gain is reduced, the noise contribution from the VCA/PGA portion becomes more significant, resulting in higher input-referred noise. However, the output-referred noise, which is indicative of the overall SNR at that gain setting, is reduced. (3) where RF is the feedback resistor (supplied externally between the LNPINP and FB terminals for each channel), A is the user-selected gain of the LNP, and RIN is the resulting amplifier input impedance with active feedback. In this case, unlike the conventional termination above, both the signal voltage and the RS noise are attenuated by the same factor of ® VCA2612 14 VCA NOISE = 3.8nV√Hz, LNP GAIN = 20dB RF RS A 14 12 ♦ × Noise Figure (dB) 10 8 6 4 2 RIN RF 1+A Active Feedback = RS LNP Noise nV/√Hz ♦ 6.0E-10 8.0E-10 1.0E-09 × 1.2E-09 1.4E-09 1.6E-09 1.8E-09 2.0E-09 RIN = RS 0 A RS 0 100 200 300 400 500 600 700 800 Source Impedance (Ω) FIGURE 7. Noise Figure for Conventional Termination. Conventional Cable Termination FIGURE 5. Configurations for Active Feedback and Conventional Cable Termination. two (6dB) before being re-amplified by the “A” gain setting. This avoids the extra 3dB degradation due to the square-root effect described above, the key advantage of the active termination technique. As mentioned above, the previous explanation ignored the input noise contribution of the LNP itself. Also, the noise contribution of the feedback resistor must be included for a completely correct analysis. The curves given in Figures 6 and 7 allow the VCA2612 user to compare the achievable noise figure for active and conventional termination methods. The left-most set of data points in each graph give the results for typical 50Ω cable termination, showing the worst noise figure but also the greatest advantage of the active feedback method. A switch, controlled by the FBSWCNTL signal on pin 45, enables the user to reduce the feedback resistance by adding an additional parallel component, connected between the LNPINP and SWFB terminals. The two different values of feedback resistance will result in two different values of active-feedback input resistance. Thus, the active-feedback impedance can be optimized at two different LNP gain settings. The switch is connected at the buffered output of the LNP and has an “ON” resistance of approximately 1Ω. When employing active feedback, the user should be careful to avoid low-frequency instability or overload problems. Figure 8 illustrates the various low-frequency time constants. Referring again to the input resistance calculation of Equation (3), and considering that the gain term “A” falls off below 3.6kHz, it is evident that the effective LNP input impedance will rise below 3.6kHz, with a DC limit of approximately RF. To avoid interaction with the feedback pole/zero at low frequencies, and to avoid the higher signal levels resulting from the rising impedance characteristic, it is recommended that the external RFCC time constant be set to about 5µs. VCA NOISE = 3.8nV√Hz, LNP GAIN = 20dB 9 8 7 Noise Figure (dB) RF VCM ♦ × 6 5 4 3 2 1 0 0 LNP Noise nV/√Hz ♦ 6.0E-10 8.0E-10 1.0E-09 × 1.2E-09 1.4E-09 1.6E-09 1.8E-09 2.0E-09 1MΩ 44pF CL Buffer RS 44pF Buffer 1MΩ Gain Stage 100 200 300 400 500 600 700 800 VCM Source Impedance (Ω) FIGURE 6. Noise Figure for Active Termination. FIGURE 8. Low Frequency LNP Time Constants. ® 15 VCA2612 Achieving the best active feedback architecture is difficult with conventional op amp circuit structures. The overall gain “A” must be negative in order to close the feedback loop, the input impedance must be high to maintain low current noise and good gain accuracy, but the gain ratio must be set with very low value resistors to maintain good voltage noise. Using a two-amplifier configuration (non-inverting for high impedance plus inverting for negative feedback reasons) results in excessive phase lag and stability problems when the loop is closed. The VCA2612 uses a patented architecture that achieves these requirements, with the additional benefits of low power dissipation and differential signal handling at both input and output. For greatest flexibility and lowest noise, the user may wish to shape the frequency response of the LNP. The COMP1 and COMP2 pins for each channel (pins 10 and 11 for channel A, pins 26 and 27 for channel B) correspond to the drains of Q3 and Q8 in Figure 4. A capacitor placed between these pins will create a single-pole low pass response, in which the effective “R” of the “RC” time constant is approximately 186Ω. LNP OUTPUT BUFFER The differential LNP output is buffered by wideband class AB voltage followers which are designed to drive low impedance loads. This is necessary to maintain LNP gain accuracy, since the VCA input exhibits gain-dependent input impedance. The buffers are also useful when the LNP output is brought out to drive external filters or other signal processing circuitry. Good distortion performance is maintained with buffer loads as low as 135Ω. As mentioned previously, the buffer inputs are AC coupled to the LNP outputs with a 3.6kHz high-pass characteristic, and the DC common mode level is maintained at the correct VCM for compatibility with the VCA input. VOLTAGE-CONTROLLED ATTENUATOR (VCA)—DETAIL The VCA is designed to have a “dB-linear” attenuation characteristic, i.e. the gain loss in dB is constant for each equal increment of the VCACNTL control voltage. Figure 9 shows a block diagram of the VCA. The attenuator is essentially a variable voltage divider consisting of one series input resistor, RS, and ten identical shunt FETs, placed in parallel and controlled by sequentially activated clipping amplifiers. Each clipping amplifier can be thought of as a specialized voltage comparator with a “soft” transfer characteristic and well-controlled output limit voltages. The reference voltages V1 through V10 are equally spaced over the 0V to 3.0V control voltage range. As the control voltage rises through the input range of each clipping amplifier, the amplifier output will rise from 0V (FET completely “ON”) to VCM –VT (FET nearly “OFF ”), where VCM is the common source voltage and VT is the threshold voltage of the FET. As each FET approaches its “OFF” state and the control voltage continues to rise, the next clipping amplifier/FET combination takes over for the next portion of the piecewiselinear attenuation characteristic. Thus, low control voltages have most of the FETs turned “ON”, while high control voltages have most turned “OFF”. Each FET acts to decrease the shunt resistance of the voltage divider formed by RS and the parallel FET network. The attenuator is comprised of two sections, with five parallel clipping amplifier/FET combinations in each. Special reference circuitry is provided so that the (VCM –VT) limit voltage will track temperature and IC process variations, minimizing the effects on the attenuator control characteristic. In addition to the analog VCACNTL gain setting input, the attenuator architecture provides digitally programmable adjustment in eight steps, via the three Maximum Gain Setting (MGS) bits. These adjust the maximum achievable gain (corresponding to minimum attenuation in the VCA, with VCACNTL = 3.0V) in 3dB increments. This function is accomplished by providing multiple FET sub-elements for each of the Q1 to Q10 FET shunt elements shown in Figure 9. In the simplified diagram of Figure 10, each shunt FET is shown as two sub-elements, QNA and QNB. Selector switches, driven by the MGS bits, activate either or both of the subelement FETs to adjust the maximum RON and thus achieve the stepped attenuation options. RS INPUT Q1A VCM Q1B Q2A Q2B Q3A Q3B Q4A Q4B Q5A OUTPUT Q5B A1 B1 B2 A2 A3 A4 A5 PROGRAMMABLE ATTENUATOR SECTION FIGURE 10. Programmable Attenuator Section. ® VCA2612 16 Attenuator Input RS Q1 A1 C1 V1 A2 C2 V2 Q2 A3 C3 V3 Q3 A4 C4 V4 Q4 A5 A1 - A10 Attenuator Stages QS Q5 A6 C5 V5 C6 V6 Q6 A7 C7 V7 Q7 A8 C8 V8 Q8 A9 C9 V9 Q9 A10 Attenuator Output VCM Q10 C10 V10 Control Input C1 - C10 Clipping Amplifiers 0dB –4.5dB Attenuation Characteristic of Individual FETs VCM-VT 0 V1 V2 V3 V4 V5 V6 V7 V8 V9 Characteristic of Attenuator Control Stage Output V10 OVERALL CONTROL CHARACTERISTICS OF ATTENUATOR 0dB –4.5dB 0.3V Control Signal 3V FIGURE 9. Piecewise Approximation to Logarithmic Control Characteristics. ® 17 VCA2612 The VCA can be used to process either differential or singleended signals. Fully differential operation will reduce 2ndharmonic distortion by about 10dB for full-scale signals. Input impedance of the VCA will vary with gain setting, due to the changing resistances of the programmable voltage divider structure. At large attenuation factors (i.e., low gain settings), the impedance will approach the series resistor value of approximately 135Ω. As with the LNP stage, the VCA output is AC coupled into the PGA. This means that the attenuation-dependent DC common-mode voltage will not propagate into the PGA, and so the PGA’s DC output level will remain constant. Finally, note that the VCACNTL input consists of FET gate inputs. This provides very high impedance and ensures that multiple VCA2612 devices may be connected in parallel with no significant loading effects. OVERLOAD RECOVERY CIRCUITRY—DETAIL With a maximum overall gain of 70dB, the VCA2612 is prone to signal overloading. Such a condition may occur in either the LNP or the PGA depending on the various gain and attenuation settings available. The LNP is designed to produce low-distortion outputs as large as 1Vp-p singleended (2Vp-p differential). Therefore the maximum input signal for linear operation is 2Vp-p divided by the LNP differential gain setting. Clamping circuits in the LNP ensure that larger input amplitudes will exhibit symmetrical clipping and short recovery times. The VCA itself, being basically a voltage divider, is intrinsically free of overload conditions. However, the PGA post-amplifier is vulnerable to sudden overload, particularly at high gain settings. Rapid overload recovery is essential in many signal processing applications such as ultrasound imaging. A special comparator circuit is provided at the PGA input which detects overrange signals (detection level dependent on PGA gain setting). When the signal exceeds the comparator input threshold, the VCA output is blocked and an appropriate fixed DC level is substituted, providing fast and clean overload recovery. The basic architecture is shown in Figure 11. Both high and low overrange conditions are sensed and corrected by this circuit. Figures 12 and 13 show typical overload recovery waveforms with MGS = 100, for VCA • PGA minimum gain (0dB) and maximum gain (36dB), respectively. LNP gain is set to 25dB in both cases. From VCA Output PGA Comparators Gain = A Selection Logic E = Maximum Peak Amplitude – EE AA FIGURE 11. Overload Protection Circuitry. VCACNTL = 0.2V, DIFFERENTIAL, MGS = 100 VCACNTL = 3.0V, DIFFERENTIAL, MGS = 100 Output Output 1V/div 1V/div Input Input 200ns/div 200ns/div FIGURE 12. Overload Recovery Response For Minimum Gain. ® FIGURE 13. Overload Recovery Response For Maximum Gain. VCA2612 18 PGA POST-AMPLIFIER—DETAIL Figure 14 shows a simplified circuit diagram of the PGA block. As described previously, the PGA gain is programmed with the same MGS bits which control the VCA maximum attenuation factor. Specifically, the PGA gain at each MGS setting is the inverse (reciprocal) of the maximum VCA attenuation at that setting. Therefore, the VCA • PGA overall gain will always be 0dB (unity) when the analog VCACNTL input is set to 0V (= maximum attenuation). For VCACNTL = 3V (no attenuation), the VCA • PGA gain will be controlled by the programmed PGA gain (24 to 45 dB in 3dB steps). For clarity, the gain and attenuation factors are detailed in Table III. MGS VCA GAIN min to max SETTING VCACNTL = 0V to 3V 000 001 010 011 100 101 110 101 –24dB to 0dB –27dB to 0dB –30dB to 0dB –33dB to 0dB –36dB to 0dB –39dB to 0dB –42dB to 0dB –45dB to 0dB DIFFERENTIAL PGA GAIN 24dB 27dB 30dB 33dB 36dB 39dB 42dB 45dB VCA • PGA GAIN min to max 0dB to 24dB 0dB to 27dB 0dB to 30dB 0dB to 33dB 0dB to 36dB 0dB to 39dB 0dB to 42dB 0dB to 45dB The PGA architecture consists of a differential, programmable-gain voltage to current converter stage followed by transimpedance amplifiers to create and buffer each side of the differential output. The circuitry associated with the voltage to current converter is similar to that previously described for the LNP, with the addition of eight selectable PGA gain-setting resistor combinations (controlled by the MGS bits) in place of the fixed resistor network used in the LNP. Low input noise is also a requirement of the PGA design due to the large amount of signal attenuation which can be inserted between the LNP and the PGA. At minimum VCA attenuation (used for small input signals) the LNP noise dominates; at maximum VCA attenuation (large input signals) the PGA noise dominates. Note that if the PGA output is used single-ended, the apparent gain will be 6dB lower. TABLE III. MGS Settings. VDD To Bias Circuitry RL Q1 Q11 Q12 Q9 RL +Out Q3 VCM RS1 RS2 +In Q2 Q5 Q6 To Bias Circuitry Q4 Q14 Q10 Q7 –In Q13 Q8 VCM –Out FIGURE 14. Simplified Block Diagram of the PGA. ® 19 VCA2612