Wideband, Low-Power, Ultra-High Dynamic Range Differential Amplifier ISL55210 Features The ISL55210 is a very wide band, Fully Differential Amplifier (FDA) intended for high dynamic range ADC input interface applications. This voltage feedback FDA design includes an independent output common mode voltage control. • Gain Bandwidth Product . . . . . . . . . . . . . . . . . . . . . . . . 4.0GHz • Input Voltage Noise . . . . . . . . . . . . . . . . . . . . . . . 0.85nV/√(Hz) • Differential Slew Rate . . . . . . . . . . . . . . . . . . . . . . . 5,600V/µs • 2VP-P, 2-tone IM3 (200Ω) 100MHz . . . . . . . . . . . . . . -109dBc Intended for very high dynamic range ADC interface applications, at the lowest quiescent power (115mW), the ISL55210 offers a 4.0GHz Gain Bandwidth Product with a very low input noise of 0.85nV/√(Hz). In a balanced differential I/O configuration, with 2VP-P output into a 200Ω load configured for a gain of 15dB, the IM3 terms are <-100dBc through 110MHz. With a minimum operating gain of 2V/V (6dB), the ISL55210 supports a wide range of higher gains with minimal BW or SFDR degradation. Its ultra high differential slew rate of 5,600V/µs ensures clean large signal SFDR performance or a fast settling step response. • Supply Voltage Range . . . . . . . . . . . . . . . . . . . . . . 3.0V to 4.2V • Quiescent Power (3.3V Supply) . . . . . . . . . . . . . . . . . .115mW Applications • Low Power, High Dynamic Range ADC Interface • Differential Mixer Output Amplifier • SAW Filter Pre/Post Driver • Differential Comms-DAC Output Driver Related Products and Literature The ISL55210 requires only a single 3.3V (max 4.2V) power supply with 35mA typical quiescent current. This industry leading low current solution can be further reduced when needed using the optional power shutdown to <0.4mA supply current. External feedback and gain setting resistors give maximum flexibility and accuracy. A companion device, the ISL55211, includes on-chip feedback and 3 possible gain setting connections where an internally fixed gain solution is preferred. The ISL55210 is available in a leadless, 16 Ld TQFN package and is specified for operation over the -40ºC to +85ºC ambient temperature range. • ISL55211 - Fixed Gain Version of the ISL55210 • ISLA112P50 - 12-bit, 500MSPS ADC (<500mW) • ISLA214P50 - 14-bit, 500MSPS ADC (<850mW) • AN1649 - Designer’s Guide to the ISL55210 and ISL55211 Evaluation Boards • AN1725 - Ultra Low Power Broadband 8 to 14-Bit Data Acquisition Platform • AN1837 - Ultra High Performance Broadband 12 to 16-Bit Data Acquisition Platform • AN1831 - Designer's Guide to the ISL55210-ABEVAL1Z Active Balun Evaluation Board +3.3V 105MHz SINGLE TONE 180mVpp for -1dBFS 10k 100 Vi 50 35mA (115mW) 495 180MHz SPAN 40.2 + PD Vcm 210 33nH - 20pF V- 500MSPS 20log ( 495 Vdiff Vi 12 Bit <500mW HD2 = -83dBc HD3 = -84dBc ENOBFS = 10.5 Bits Vdiff 40.2 100 ISLA112P50 20pF 210 Vb ISL55210 0.1µF ADT4-1WT V+ 33nH 0.1µF 1:2 0.1µF SNRFS = 64.9dBFS 500kHz CLK ) = 17.3dB gain FIGURE 1. TYPICAL APPLICATION CIRCUIT June 6, 2013 FN7811.2 1 CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures. 1-888-INTERSIL or 1-888-468-3774 | Copyright Intersil Americas LLC 2011-2013. All Rights Reserved Intersil (and design) is a trademark owned by Intersil Corporation or one of its subsidiaries. All other trademarks mentioned are the property of their respective owners. ISL55210 Pin Configuration ISL55210 (3x3 16 LD TQFN) TOP VIEW FB+ 1 V i- 2 GND V S+ V CM GND 16 15 14 13 - 12 V O+ 11 NC 10 NC 9 V O- V CM V i+ 3 FB- 4 + 5 6 GND V S+ 7 8 GND PD GND Pin Descriptions PIN NUMBER SYMBOL DESCRIPTION 1 FB+ 2 Vi- Inverting Amplifier Input 3 Vi+ Noninverting Amplifier Input 4 FB- Negative Output Feedback resistor connection 5, 8, 13, 16 GND Supply Ground (Thermal Pad Electrically Connected) 6, 15 VS+ Positive power supply (3.0V~4.5V) 7 PD Power-down: PD = logic low puts part into low power mode, PD = logic high or 1kΩ to VS+ for normal operation 9 VO- Inverting Amplifier Output 10, 11 NC No Internal Connection 12 VO+ Noninverting Amplifier Output 14 VCM Common-mode Voltage Input Positive Output Feedback resistor connection Ordering Information PART NUMBER (Notes 1, 2, 3) PART MARKING TEMP RANGE (°C) PACKAGE (Pb-free) TRANSPORT MEDIA, QUANTITY PKG. DWG. # ISL55210IRTZ 5210 -40 to +85 16 Ld 3x3 TQFN L16.3x3D ISL55210IRTZ-T7 5210 -40 to +85 16 Ld 3x3 TQFN Tape and Reel, 1000 L16.3x3D ISL55210IRTZ-T7A 5210 -40 to +85 16 Ld 3x3 TQFN Tape and Reel, 250 L16.3x3D ISL55210IRTZ-EVALZ Evaluation Board (Contact local sales) NOTES: 1. Please refer to TB347 for details on reel specifications. 2. These Intersil Pb-free plastic packaged products employ special Pb-free material sets, molding compounds/die attach materials, and 100% matte tin plate plus anneal (e3 termination finish, which is RoHS compliant and compatible with both SnPb and Pb-free soldering operations). Intersil Pbfree products are MSL classified at Pb-free peak reflow temperatures that meet or exceed the Pb-free requirements of IPC/JEDEC J STD-020. 3. For Moisture Sensitivity Level (MSL), please see device information page for ISL55210. For more information on MSL please see techbrief TB363. 2 FN7811.2 June 6, 2013 ISL55210 Absolute Maximum Ratings (TA = +25°C) Thermal Information Supply Voltage from VS+ to GND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .4.5V Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .VS+ +0.3V to GND-0.3V Power Dissipation (See “Power Supply, Shutdown, and Thermal Considerations” on page 13) ESD Rating Human Body Model (Per MIL-STD-883 Method 3015.7) . . . . . . . . 3500V Machine Model (Per EIAJ ED-4701 Method C-111) . . . . . . . . . . . . . 250V Charged Device Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1500V Latch up (Per JESD-78; Class II; Level A) . . . . . . . . . . . . . . . . . . . . . . 100mA Thermal Resistance (Typical) θJA (°C/W) θJC (°C/W) 16 Ld TQFN Package (Notes 4, 5) . . . . . . . 63 16.5 Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .-65°C to +125°C Maximum Continuous Operating Junction Temperature. . . . . . . . . . .+135°C Pb-Free Reflow Profile . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . see link below http://www.intersil.com/pbfree/Pb-FreeReflow.asp Recommended Operating Conditions Ambient Operating Temperature . . . . . . . . . . . . . . . . . . . . . -40°C to +85°C CAUTION: Do not operate at or near the maximum ratings listed for extended periods of time. Exposure to such conditions may adversely impact product reliability and result in failures not covered by warranty. NOTES: 4. θJA is measured in free air with the component mounted on a high effective thermal conductivity test board with “direct attach” features. See Tech Brief TB379. 5. For θJC, the “case temp” location is the center of the exposed metal pad on the package underside. Electrical Specifications VS+ = +3.3V Test Conditions: G = 12dB, VCM = open, VO = 2VP-P, RF = 200Ω, RL = 200Ω differential, TA = +25°C, differential input, differential output, input and output referenced to internal default VCM (1.2V nominal) unless otherwise specified. PARAMETER CONDITIONS MIN (Note 6) TYP MAX (Note 6) UNIT TESTED (Note 7) AC PERFORMANCE Small-Signal Bandwidth (4-port S parameter, Test Circuit #2) G = 12dB, VO = 100mVP-P 2,200 MHz G = 18dB, VO = 100mVP-P 700 MHz G = 24dB, VO = 100mVP-P 300 MHz Gain-Bandwidth Product G = 18dB 4.0 GHz Bandwidth for 0.1-dB Flatness G = 12dB, VO = 100mVP-P 200 MHz Large-Signal Bandwidth G = 12dB, VO = 2VP-P 1.2 GHz 5,600 V/µs Slew Rate (Differential) Differential Rise/Fall Time 2-V step 0.17 ns 2nd-order Harmonic Distortion f = 20MHz, VO = 2VP-P -105 dBc f = 50MHz, VO = 2VP-P -88 dBc f = 100MHz, VO = 2VP-P -72 dBc f = 20MHz, VO = 2VP-P -120 dBc f = 50MHz, VO = 2VP-P -107 dBc f = 100MHz, VO = 2VP-P -95 dBc fc = 70MHz, 200kHz spacing (2VP-P envelope) -80 dBc fc = 140MHz, 200kHz spacing (2VP-P envelope) -68 dBc fc = 70MHz, 200kHz spacing (2VP-P envelope) -102 dBc fc = 140MHz, 200kHz spacing (2VP-P envelope) -94 dBc Input Voltage Noise f > 1MHz, Differential 0.85 nV/√HZ Input Current Noise f > 1MHz, Each Input 5.0 pA/√HZ 3rd-order Harmonic Distortion 2nd-order Intermodulation Distortion 3rd-order Intermodulation Distortion 3 FN7811.2 June 6, 2013 ISL55210 Electrical Specifications VS+ = +3.3V Test Conditions: G = 12dB, VCM = open, VO = 2VP-P, RF = 200Ω, RL = 200Ω differential, TA = +25°C, differential input, differential output, input and output referenced to internal default VCM (1.2V nominal) unless otherwise specified. (Continued) PARAMETER CONDITIONS MIN (Note 6) TYP MAX (Note 6) UNIT TESTED (Note 7) dB * * DC PERFORMANCE Open-loop Voltage Gain (AOL) Differential 86 100 Input Offset Voltage TA = +25°C -1.4 ±0.1 +1.4 mV TA = -40°C to +85°C -1.6 ±0.1 +1.6 mV Average Offset Voltage Drift TA = -40°C to +85°C ±3 Input Bias Current TA = +25°C, positive current into the pin +50 +120 µA TA = -40°C to +85°C +50 +140 µA Average Bias Current Drift TA = -40°C to +85°C +200 Input Offset Current TA = +25°C -5 ±1 +5 µA TA = -40°C to +85°C -6 ±1 +6 µA TA = -40°C to +85°C Average Offset Current Drift µV/°C * nA/°C ±8 * nA/°C INPUT Common-mode Input Range High 1.7 Common-mode Input Range Low V * V * 75 dB * 1 || 2 kΩ || pF 2.35 V * V * VP-P * 1.1 Common-mode Rejection Ratio f < 10MHz, common mode to differential output 56 Differential Input Impedance OUTPUT Maximum Output Voltage Minimum Output Voltage Differential Output Voltage Swing Each output (with 200Ω differential load) Linear Operation 2.15 TA = +25°C 3.04 TA = -40°C to +85°C 2.95 Differential Output Current Drive RL = 10Ω [sourcing or sinking] Closed-loop Output Impedance f < 10MHz, differential 0.45 40 0.63 3.8 V 45 mA 0.6 Ω * OUTPUT COMMON-MODE VOLTAGE CONTROL Small-signal Bandwidth From VCM pin to Output VCM 30 MHz Slew Rate Rising/Falling 150 V/µs Gain VCM input pin 1.0V to 1.4V 0.995 0.999 V/V * -8 ±1 +8 mV * 1.18 1.2 1.22 V * Output Common-Mode Offset from CM Input CM Default Voltage Output VCM with VCM pin floating CM Input Bias Current At control pin CM Input Voltage Range At control pin CM Input Impedance At control pin 2 0.9 µA 1.9 15 || 50 V * kΩ || pF POWER SUPPLY Specified Operation Voltage Quiescent Current TA = +25°, VS+ = 3.3V, VS- = 0V TA = -40°C to +85°C Power-supply Rejection (PSRR) VS+ 4 3.0V - 4.5V range 3 3.3 4.2 V 33 35 37 mA 30.5 36 39.5 mA 56 90 dB * * FN7811.2 June 6, 2013 ISL55210 Electrical Specifications VS+ = +3.3V Test Conditions: G = 12dB, VCM = open, VO = 2VP-P, RF = 200Ω, RL = 200Ω differential, TA = +25°C, differential input, differential output, input and output referenced to internal default VCM (1.2V nominal) unless otherwise specified. (Continued) PARAMETER CONDITIONS MIN (Note 6) TYP MAX (Note 6) UNIT TESTED (Note 7) 1.3 1.55 V * V * * POWER-DOWN Referenced to GND Enable Voltage Threshold Assured on above 1.55V Disable Voltage Threshold Assured off below 0.54V 0.54 0.7 Power-down Quiescent Current TA = +25°C 0.2 0.3 0.4 mA TA = -40°C to +85°C 0.15 0.3 0.45 mA PD = 0V, current positive into pin Input Bias Current Input Impedance -2 µA 2 || 5 MΩ || pF Turn-on Time Delay Measured to output on 200 ns Turn-off Time Delay Measured to output off 400 ns NOTES: 6. Compliance to datasheet limits is assured by one or more methods: production test, characterization, and/or design. 7. Parameters denoted by an “*” are ATE tested. 5 FN7811.2 June 6, 2013 ISL55210 Typical Performance Curves VS+ = 3.3V, TA ≈ +25°C, unless otherwise noted. 18 6 VO = 3VP-P SLEW LIMITING 15dB 0 15 21dB -3 -6 -9 GAIN (dB) NORMALIZED GAIN (dB) 3 27dB -12 INPUT TRANSFORMER 12 VO = 1VP-P +2VP-P 9 -15 33dB -18 6 -21 TEST CIRCUIT #1, RL = 200Ω, VO = 500mVP-P DIFFERENTIAL -24 107 108 FREQUENCY (Hz) TEST CIRCUIT #1 3 106 107 109 FIGURE 2. FREQUENCY RESPONSE vs GAIN SETTING 6.0 IM2 15dB GAIN -85 IM2 21dB GAIN IM3 15dB GAIN IM3 21dB GAIN -105 -115 TEST CIRCUIT #1, RL = 200Ω, VOP-P = 1VP-P EACH TONE 100 150 200 OUTPUT COMPRESSION POINT (VP-P, DIFFERENTIAL) 2-TONE IM SPURIOUS (dBc) -75 -125 50 5.5 RL = 200Ω 5.0 RL = 100Ω 4.5 RL = 50Ω 4.0 3.5 TEST CIRCUIT #1 3.0 50 100 250 150 TEST FREQUENCIES CENTER (MHz) 250 FIGURE 5. OUTPUT VP-P FOR -1dB GAIN COMPRESSION 12 12 11 11 GAIN = 15dB GAIN = 18dB NOISE FIGURE (dB) NOISE FIGURE (dB) 200 FREQUENCY (MHz) FIGURE 4. IM2 AND IM3 vs GAIN 10 9 GAIN = 21dB 8 7 TEST CIRCUIT #1 6 50 109 FIGURE 3. FREQUENCY RESPONSE vs OUTPUT SWING -65 -95 108 FREQUENCY (Hz) 200 350 FREQUENCY (MHz) FIGURE 6. NOISE FIGURE 6 500 10 GAIN = 24dB 9 8 7 TEST CIRCUIT #1 WITH ADT4-1T INPUT AND RG = 100Ω, RF = 400Ω 6 50 200 350 500 FREQUENCY (MHz) FIGURE 7. NOISE FIGURE AT HIGHER GAINS FN7811.2 June 6, 2013 ISL55210 Typical Performance Curves HD2 3VP-P -70 HD2/HD3 SPURIOUS (dBc) -60 TEST CIRCUIT #1, RL = 200Ω HD2 2VP-P -80 HD3 3VP-P -90 HD2 1VP-P -100 -110 HD3 1VP-P IM2 AND IM3 SPURIOUS (dBc) -60 VS+ = 3.3V, TA ≈ +25°C, unless otherwise noted. (Continued) TEST CIRCUIT #1, RL = 200Ω IM2 3VP-P -70 IM2 2VP-P -80 IM2 1VP-P IM3 3VP-P -90 -100 IM3 2VP-P -110 HD3 2VP-P -120 20 -120 200 100 IM3 1VP-P 20 FIGURE 9. IM2 AND IM3 vs OUTPUT SWING FIGURE 8. HD2/HD3 vs VOPP -65 HD2, GAIN = 15dB HD2, GAIN = 21dB HD2, GAIN = 27dB -90 HD3, GAIN = 15dB -100 HD3, GAIN = 21dB -110 IM2 AND IM3 SPURIOUS (dBc) HD2 AND HD3 DISTORTION (dBc) -60 TEST CIRCUIT #1 -80 TEST CIRCUIT #1 -75 IM2 GAIN = 15dB -85 IM3 GAIN = 21dB -95 -105 IM3 GAIN = 27dB IM3 GAIN = 27dB IM3 GAIN = 21dB -115 IM3 GAIN = 15dB HD3, GAIN = 27dB -120 20 100 -125 20 200 FREQUENCY (MHz) FIGURE 10. HD2 AND HD3 vs GAIN 100 TEST FREQUENCIES CENTER (MHz) 200 FIGURE 11. IM2 AND IM3 vs GAIN -50 -50 HD2, 50Ω -60 -60 HD2, 100Ω -70 HD2, 200Ω -80 HD3, 50Ω -90 HD2, 500Ω HD3, 100Ω -100 IM SPURIOUS (dBc) DISTORTION (dBc) 200 TEST FREQUENCIES CENTER (MHz) FREQUENCY (MHz) -70 100 -70 -80 IM3, 100Ω -90 IM2, 200Ω -100 HD3, 200Ω -110 -110 IM2, 100Ω IM2, 50Ω IM3, 500Ω IM2, 500Ω HD3, 500Ω -120 20 100 FREQUENCY (MHz) FIGURE 12. HD2 AND HD3 vs RLOAD 7 IM3, 200Ω 200 -120 20 100 200 CENTER FREQUENCY (MHz) FIGURE 13. IM2 AND IM3 vs RLOAD FN7811.2 June 6, 2013 ISL55210 GROUP DELAY, G = 27dB 165 1.6 150 1.5 PHASE, G = 15dB PHASE (°) 135 1.4 120 1.3 105 1.2 GROUP DELAY G = 21dB 90 1.1 GROUP DELAY G = 15dB 75 60 PHASE G = 21dB TEST CIRCUIT #2 45 10 40 70 100 130 FREQUENCY (MHz) 10.0 1.7 1.0 PHASE G = 27dB VOLTAGE NOISE (nV/√Hz) AND CURRENT NOISE (pA/√Hz) 180 VS+ = 3.3V, TA ≈ +25°C, unless otherwise noted. (Continued) GROUP DELAY (ns) Typical Performance Curves 1.0 EN (DIFFERENTIAL) 0.9 0.8 190 160 IN (EACH INPUT) 0.1 105 RF = 1.6kΩ -6 RF = 806Ω -12 -15 -18 4-PORT S21 TEST, TEST CIRCUIT #2 -21 107 108 FREQUENCY (Hz) CLOSED LOOP OUTPUT IMPEDANCE (Ω) NORMALIZED DIFFERENTIAL GAIN (dB) 0 -9 10 8 7 6 GAINS 12dB TO 30dB 5 4 3 2 1 0 109 SIMULATED TEST, TEST CIRCUIT #2 9 1 -45 GAIN (dB) OUTPUT VCM vs VDIFF (dB) 0 200mVP-P 10mVP-P -9 -12 -15 -18 TEST CIRCUIT #3 COMMON MODE AC OUTPUT -21 1 10 FREQUENCY (MHz) 100 FIGURE 18. VCM PIN INPUT FREQUENCY RESPONSE TO OUTPUT COMMON MODE 8 100 1000 FIGURE 17. DIFFERENTIAL OUTPUT IMPEDANCE 3 -6 10 FREQUENCY (MHz) FIGURE 16. SMALL SIGNAL RESPONSE vs GAIN -3 108 FIGURE 15. INPUT VOLTAGE AND CURRENT SPOT NOISE RF = 200Ω RF = 402Ω -3 107 FREQUENCY (Hz) FIGURE 14. PHASE AND GROUP DELAY vs GAIN 3 106 200 TEST CIRCUIT #3 COMMON MODE AC OUTPUT MEASUREMENTS -50 -55 -60 -65 -70 -75 2 10 TEST FREQUENCY (MHz) 100 200 FIGURE 19. OUTPUT BALANCE ERROR FN7811.2 June 6, 2013 ISL55210 Typical Performance Curves VS+ = 3.3V, TA ≈ +25°C, unless otherwise noted. (Continued) 0.15 1.5 OUTPUT OUTPUT 1.0 0.05 AMPLITUDE (V) AMPLITUDE (V) 0.10 INPUT 0 -0.05 -0.10 0.5 INPUT 0 -0.5 -1.0 TEST CIRCUIT #1, 50MHz SQUARE WAVE INPUT -0.15 0 10 20 30 TEST CIRCUIT #1, 50MHz SQUARE WAVE INPUT 40 -1.5 50 0 5 10 15 20 TIMEBASE (ns) FIGURE 20. SMALL SIGNAL STEP RESPONSE 25 30 TIME (ns) 35 40 45 50 FIGURE 21. LARGE SIGNAL STEP RESPONSE 0 100MHz OUTPUT TEST CIRCUIT #1 FEEDTHROUGH (dB) -2 ENABLED PD DISABLED -4 100mVP-P INPUT -6 -8 -10 -12 2VP-P INPUT -14 -16 TEST CIRCUIT #1 2µs/DIV 1 FIGURE 22. ENABLE/DISABLE TIMES 95 OUTPUT PSRR TO VO (DIFFERENTIAL) 2.0 85 1.5 1.0 INPUT 0.5 0 -0.5 -1.0 -1.5 -2.0 -2.5 100 FIGURE 23. DISABLED FEEDTHROUGH PSRR/CMRR (dB) INPUT AND OUTPUT WAFEFORMS (V) 2.5 10 FREQUENCY (MHz) 75 CMRR TO VO (DIFFERENTIAL) 65 55 45 TEST CIRCUIT #1 SIMULATED, EXACT EXTERNAL R’s TEST CIRCUIT #1 0 20 40 60 80 100 120 TIME (ns) 140 FIGURE 24. OVERDRIVE RECOVERY 9 160 180 200 35 1 10 100 1000 FREQUENCY (MHz) FIGURE 25. PSRR/CMRR TO DIFFERENTIAL VO FN7811.2 June 6, 2013 ISL55210 Typical Performance Curves TEST CIRCUIT #1 5 4 MAXIMUM DIFFERENTIAL VP-P OUTPUT USING DEFAULT VCM 3 2 SUPPLY CURRENT (mA) OUTPUT DEFAULT VCM AND MAX DIFFERENTIAL VOPP (V) 6 VS+ = 3.3V, TA ≈ +25°C, unless otherwise noted. (Continued) INTERNALLY SET VCM 1 3.0 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 3.9 4.0 4.1 4.2 4.3 4.4 4.5 SUPPLY VOLTAGE (V) 45 TEST CIRCUIT #1 44 43 TA = +85°C 42 41 40 39 38 TA = +25°C 37 36 35 TA = -40°C 34 33 32 31 30 3.0 3.1 3.2 3.3 3.4 3.5 3.6 3.7 3.8 3.9 4.0 4.1 4.2 4.3 4.4 4.5 SINGLE SUPPLY VOLTAGE (V) FIGURE 26. DEFAULT VCM AND MAX VOPP vs SUPPLY VOLTAGE Applications Basic Operation The ISL55210 is a very wideband, voltage feedback based, differential amplifier including an output common mode control loop and optional power shutdown feature. Intended for very low distortion differential signal driving, this non-unity gain stable device also delivers extremely low input noise terms of 0.85nV/√Hz and 5pA/√Hz. Most applications are intended for AC coupled I/O using a single 3.3V supply. It will operate over a single supply range of 3.0V to 4.2V. Where DC coupled operation is desired, using split power supplies will allow the ISL55210 I/O common mode range limits to be observed while giving either a differential I/O or single to differential configuration. Most applications behave as a differential inverting op amp design. There is, therefore, an input gain resistor on each side of the inputs that must be driven. To retain overall low output noise, these resistors are normally of low value. The device can be powered down to <400µA supply current using the optional disable pin. To operate normally, this pin should be asserted high using a simple logic gate to +VS or tied high through a 10kΩ resistor to +VS. When disabled, the power dissipation drops to <1mW but, due to the inverting op amp type architecture, the input signal will feed forward through the external resistors giving limited isolation. Application and Characterization Circuits The circuit of Figure 28 forms a starting point for many of the characterization curves for the ISL55210. Since most lab sources and measurement devices are single-ended, this circuit converts to differential at the input through a wideband transformer and would also be a typical application circuit coming from a single ended source. Assuming the source is a 50Ω impedance, the RG resistors are set to provide both the input termination and the gain. Since the inverting summing nodes act as virtual ground points for AC signal analysis, the total termination impedance across the input transformer secondary will be 2 * RG. Setting this equal to n2*RS will give a matched input impedance inside the bandwidth of the transformer (where "n" is the turns ratio). The amplifier gain is then set by adjusting the feedback resistors 10 FIGURE 27. SUPPLY CURRENT vs SUPPLY VOLTAGE values. Since the ISL55210 is a VFA design, increasing the feedback resistor to get higher gain does not directly reduce the bandwidth as it would with a CFA based design. This gives increased flexibility in the input turns ratio and overall gain setting (while holding a matched input impedance) over alternate solutions. +3.3V 33mA 110mW 200 RF 50 50 1:1.4 VI 10k 85 + RG 1µF PD 200 1µF 0.1uF VCM 50 35 200 VO LOAD 1µF VM ISL55210 ADT2-1T 35 RG 1:1 - 50 ADT1-1WT 1µF 85 RF 200 FIGURE 28. TEST CIRCUIT #1 Working with a transformer coupled input as shown in Figure 28, or with two DC blocking caps from a differential source, means the output common mode voltage set by either the default internal VCM setting, or a voltage applied to the VCM control pin, will also appear as the input common mode voltage. This provides a very easy way to control the ISL55210 I/O common mode operating voltages for an AC coupled signal path. The internal common mode loop holds the output pins to VCM and, since there is no DC path for an ICM current back towards the input in Figure 28, that VCM setting will also appear as the input common mode voltage. It is useful, for this reason, to leave any input transformer secondary centertap unconnected. The internally set VCM voltage is referenced from the negative supply pin. With a single 3.3V supply, it is very close to 1.2V but will change with total supply voltage across the device as shown in Figure 26. FN7811.2 June 6, 2013 ISL55210 Most of the characterization curves start with Figure 28 then get different gains by changing the feedback resistor, RF, use different input transformers where then the RG is also adjusted to hold an input match, or vary the loading. For load tests below the 200Ω shown in Figure 28, a simple added shunt resistor is placed across the output pins. For loads >200Ω, the series and shunt load R's are adjusted to show that total load (including the 50Ω measurement load reflected through the 1:1 output measurement port transformer) and provide an apparent 50Ω differential source to that transformer. This output side transformer is for measurement purposes only and is not necessary for final applications circuits. There are output interface designs that do benefit from a transformer as part of the signal path, but the one shown at the right of Figure 28 is used only for characterization to get a doubly terminated 50Ω measurement path going differential to single ended. Where just the amplifier is tested, a 4 port network analyzer is used and the very simple test circuit of Figure 29 is implemented. This is used to extract the differential S21 curves and differential output impedance vs gain. Changing the gain is a simple matter of adjusting the two RF resistors of Figure 29. This circuit depends on the two AC coupled source 50Ω of the 4 port network analyzer and presents an AC coupled differential 100Ω load to the amplifier as the input impedance of the remaining two ports of the network analyzer. impedance that increases with signal gain setting. The ISL55210 holds a more constant response vs gain due to internal design elements unique to this device. Common mode output measurements are made using the circuit Figure 30. Here, the outputs are summed together through two 100Ω resistors (still a 200Ω differential load) to a center point where the average, or common mode, output voltage may be sensed. This is coupled through a 1µF DC blocking capacitor and measured using 50Ω test equipment. The common mode source impedance for this circuit is the parallel combination of the 2Ω - 100Ω elements, or 50Ω. Figure 18 uses this circuit to measure the small and large signal response from the VCM control pin to the output common mode. This pin includes an internal 50pF capacitor on the default bias network (to filter supply noise when there is no connection to this pin) which bandlimits the response to approximately 30MHz. This is far lower than the actual bandwidth of the common mode loop. Figure 19 uses this output CM measurement circuit with a large signal (2VP-P) differential output voltage (generated through the Vi path of Figure 30) to measure the differential to common mode conversion. +3.3V 200 10k +3.3V 50 RF Vi PD 10k 50 50 50 + 1µF V CM VCM ISL55210 50 50 50 100 200 VCM INPUT - 1µF ISL55210 50 1/2 OF A 4-PORT S-PARAMETER 50 OUTPUT VCM ADT2-1T PD 1/2 OF A 4-port S-PARAMETER 100 + 1:1.4 50 FIGURE 30. TEST CIRCUIT #3 COMMON MODE AC OUTPUT MEASUREMENTS RF FIGURE 29. TEST CIRCUIT #2 4-PORT S-PARAMETER MEASUREMENTS Using this measurement allows the full small single bandwidth of the ISL55210 to be exposed. Many of the other measurements are using I/O transformers that are limiting the apparent bandwidth to reduced level. Figure 16 shows a series of normalized differential S21 curves for gains of 12dB to 30dB in 6dB steps. These are simply stepping two feedback resistor values (RF) up from 200Ω to 1600Ω in 2X steps. The lowest gain of 12dB (4V/V) is showing a 2.2GHz small signal bandwidth. This response gets some bandwidth extension due to phase margin <60degree effects, but by the gain of 24dB (16V/V), the bandwidth is following a Gain Bandwidth type characteristic showing 300MHz bandwidth or >4GHz Gain Bandwidth Product (GBP). The closed loop differential output impedance of Figure 17 is simulated using Figure 29 in ADS. This shows a relatively low output impedance (<1Ω through 100MHz) constant with signal gain setting. Typical FDA outputs show a closed loop output 11 Single Supply, Input Transformer Coupled, Design Considerations The characterization circuit of Figure 28 shows one possible input stage interface that offers several advantages. The ISL55210 can also support a DC coupled differential to differential or single ended input to differential requirement if needed. Where AC coupling is adequate, the circuit of Figure 28 simplifies the input common mode voltage control. If the source coming into this stage is single ended, the input transformer provides a zero power conversion to differential. The two gain resistors (RG in Figure 28) provide both the input termination impedance and the gain element for the amplifier. For minimum noise, only RG should be used and set to achieve the desired input impedance. Since the ISL55210 is a VFA device, these resistor values can be scaled up and down a bit more freely than a current feedback based FDA. FN7811.2 June 6, 2013 ISL55210 For instance, if a minimum noise configuration is not required, but it is desirable to increase the feedback resistors to reduce the added loading they present to the output stage, the RG and RF resistors can be scaled up to achieve the same gain with an additional termination resistance added across the input transformer to adjust the termination impedance. Figure 31 shows an example using a 1:2 input turns ratio where the RG and RF elements have been scaled up and a shunt termination resistance added. This example provides a single to differential signal gain of 20dB and input impedance of 50Ω to the source. The 1:2 turn ratio transformer needs a 200Ω differential secondary impedance to provide an input side 50Ω match. This is provided here by the parallel combination of the 2Ω - 200Ω RG resistors and the 400Ω parallel impedance at the transformer secondary. +3.3V 1k RF 200 50 Vi 1µF + RG 1:2 V CM 400 ISL55210 VO ADT41WT RG - 200 RF 1k FIGURE 31. SINGLE TO DIFFERENTIAL WITH REDUCED FEEDBACK LOADING The examples shown are using the transformer to convert from single to differential. However, if the source is already differential, these same transformer input circuits can drive the transformer differentially still providing impedance scaling if needed and common mode rejection for both DC and AC common mode issues. A good example would be differential mixer outputs or SAW filter outputs. Those differential sources could also be connected into the ISL55210 RG resistors through blocking caps as well eliminating the input transformer. The AC termination impedance for the differential source will then be the sum of the two RG resistors when simple blocking caps are used. Amplifier I/O Range Limits The ISL55210 is intended principally to give the lowest IM3 performance on the lowest power for a differential I/O application. The amplifier will work DC coupled and over a relatively wide supply range of 3.0V to 4.2V supplies. The outputs have both a differential and common mode operating range while the input pins have a common operating range. For single supply operation, the ground pins are at ground as is the exposed metal pad on the underside of the package. The ISL55210 can operate split supply where then the ground pins will be a negative supply voltage and the exposed metal pad is either connected to this negative supply or left unconnected on an insulating board layer. Briefly, the I/O and VCM limits are: 1. Maximum VCM setting = -VS + 2V 2. Input common mode operating range of -VS + 1.1V or the output VCM + 0.5V 3. Output VO minimum (on each side) is either -VS + 0.3V or output VCM - 0.9V 4. Output VO maximum (on each side) is +VS - 1.5V This circuit has scaled the feedback resistor up to 1kΩ to still achieve the amplifier gain of 5V/V which gives the overall gain of 10V/V (20dB) when the 1:2 step up at the input is considered. The particular transformer shown is typical of 1:2 turns ratio broadband transformers, but there a many alternates with the similar or improved characteristics. This input interface also simplifies the input common mode control. The VCM pin controls the output common mode voltage. In most DC coupled FDA applications, the input common mode voltage is determined by both this output common mode and the source signal. In a configuration like Figure 31, there is no path for a common mode current to flow from output to input, so the input common mode voltage equals the output. A similar effect could be achieved with just two blocking caps on the two RG resistors. A DC coupled, single to differential, configuration will also have a common mode input that is moving with the input signal. Converting to just a differential signal at the amplifier, as in Figure 31, removes any input signal related artifacts from the input common mode making the ISL55210 behave as a differential only VFA amplifier. There is only a very small differential error signal at the inputs set by the loop gain, as in a normal single ended VFA application, but no common mode signal related terms. 12 The output swing limits are often asymmetrical around the VCM voltage. The maximum single ended swings are set by these two limits: VOMIN is either -VS + 0.3V or VCM - 0.9V whichever is less. So for instance on a single 3.3V supply with the default VCM voltage of 1.2V, these two limits give the same result and the output pins can swing down to 0.3V above -VS = 0V. If, however, the VCM pin is raised to 1.5V, then the minimum output voltage will become 1.5V - 0.9V = 0.6V. VOMAX is set by a headroom limit to the positive supply to be: VOMAX = +VS - 1.5V. Again, on a 3.3V single supply and the default 1.2V VCM setting, this mean the maximum referenced to ground output pin voltages can be 3.3V - 1.5V = +1.8V or 0.6V above the default VCM voltage. Using these default conditions, and the maximum positive excursion of 0.6V above the 1.2V output VCM setting, the maximum differential VP-P swing will be 4X this 0.6V single ended limit or 2.4VP-P. Where +VS is increased the limit then becomes the 0.9V below VCM, but then the absolute maximum differential VP-P is then 4X 0.9V to 3.6VP-P. So, for instance, to get this maximum output swing, increase the supply voltage until +VS - 1.5V > VCM + 0.9V. If we assume a VCM voltage of 1.3V for instance, then 1.3V + 0.9V + 1.5V = 3.7V will give an unclipped FN7811.2 June 6, 2013 ISL55210 3.6VP-P output capability. The VP-P reported in Figure 26 is an asymmetrically clipped maximum swing. Going 10% above this 3.7V target to 4.1V will be within the recommended operating range and give some tolerancing headroom that would also suggest the VCM voltage be moved up to approximately 1.5V. This coincides with the default output VCM from Figure 26. Operating at +4.1V single supply in a Figure 28 type configuration will give the maximum linear available output swing of 3.6VP-P. The differential inputs of the ISL55210 also have operating range limits relative to the supply voltages. Operating in an AC coupled circuit like Figure 28 will produce an input common mode voltage equal to the outputs. The inputs can operate with full linearity with this VCM voltage down to 1.1V above the GND connection (or -VS supply). On the default 1.2V output VCM on +3.3V supplies this gives a 100mV guardband on the input VCM voltages. Overriding the default VCM by applying a control voltage to the VCM pin should be done with care in going towards the negative supply due to this limit. On the + side, the maximum VCM above the -VS supply is 2V so there is more room to move the output VCM up than down from the default value. When operated as a DC coupled single to differential amplifier, the input common mode voltage will move with the input signal and will be different than the output common mode voltage when the external resistors are set for gain. When the input common mode can be different than the output, the additional constraint that must be observed is that the input common mode voltage cannot be > output VCM +0.5V. This would only occur if the single source was coming from a higher voltage than the output VCM setting. Power Supply, Shutdown, and Thermal Considerations The ISL55210 is intended for single supply operation from 3.0V to 4.2V with an absolute maximum setting of 4.5V. The 3.3V supply current is trimmed to be nominally 35mA at +25°C ambient. Figure 27 shows the supply current for nominal +25°C and -40°C to +85°C operation over the specified maximum supply range. The input stage is biased from an internal voltage referenced from the negative supply giving the exceptional 90dB low frequency PSRR shown in Figure 25. Since the input stage bias is from a re-regulated internal supply, a simple approach to single +5V operation can be supported as shown in Figure 32. Here, a simple IR drop from the +5V supply will bring the operating supply voltage for the ISL55210 into its allowed range. Figure 32 shows example calculations for the voltage range at the ISL55210 +VS pin assuming a ±5% tolerance on the +5V supply and a 35mA to 55mA range on the total supply current. Considering the 34mA to 44mA quiescent current range from Figure 27 over the -40°C to +85°C ambient, and the 3.4V to 4.4V supply voltage range assumed here, this is designing for a 1mA to 11mA average load current which should be adequate for most intended application loads. Good supply decoupling at the device pins is required for this simple solution to still provide exceptional SFDR performance. 13 +5V ±5% 35 24.3 3.4 55mA + RF 4.4V 2.2µF 10nF 10k + C in 1:n RO RG PD V CM Vi VO ISL55210 RO RG - RF FIGURE 32. OPERATING FROM A SINGLE +5V SUPPLY The ISL55210 includes a power shutdown feature that can be used to reduce system power dissipation when signal path operation is not required. This pin (PD) is referenced to the ground pins and must be asserted low to activate the shutdown feature. When not used, a 10kΩ external resistor to +VS should be used to assert a high level at this pin. Digital control on this pin can be either an open collector output (using that 10kΩ pullup) or a CMOS logic line running off the same +VS as the amplifier. For split supply operation, the PD pins must be pulled to below -VS + 0.54V to disable. Since the ISL55210 operates as a differential inverting op amp, there is only modest signal path isolation when disabled as shown in Figure 23. For small input signals, Figure 23 shows about 5dB to 6dB isolation while for large signals, back to back protection diodes across the inputs compress the signal to show actually an improved isolation. This is intended to protect any subsequent devices from large input signals during shutdown. Those diodes limit the maximum overdrive voltage across the input to approximately 0.5V in each polarity. The RG resistors of Test Circuit #1 limit the current into those diodes under this condition. The supply current in shutdown does not reduce to zero as internal circuitry is still active to hold the output common mode voltage at the VCM control input voltage even during shutdown (or the default value). This is intended to hold the ISL55210 output near the desired common mode output level during shutdown. This improves turn on characteristic and keeps the output voltages in a safe range for downstream circuitry. DISABLED OPERATION WARNING IN DC COUPLED DESIGNS When disabled, the output stage provides a nominal DC voltage at the Vcm control pin input or the default internal 1.2V value. Being very low power, any external circuit condition that can cause the output pins to source or sink DC current can move the ISL55210 internal operating points into regions from which it may not recover when the device is enabled. If the external circuitry can force >20µA into the output pins or pull > 1.5mA out of the output pins correct operation is not guaranteed. For designs that might force current into the output stage during disable, adding a resistor to ground on the outputs might provide FN7811.2 June 6, 2013 ISL55210 an effective means of turning that into a low sourcing current condition with minimal impact to the desired signal path operation when enabled. With equal feedback and gain resistors, the total output noise expression becomes very simple. This is: The very low internal power dissipation of the ISL55210, along with the excellent thermal conductivity of the QFN package when the exposed metal pad is tied to a conductive plate, reduces the TJ rise above ambient to very modest levels. Assuming a nominal 115mW dissipation and using the +63°C/W measured thermal impedance from Junction to ambient, gives a rise of only 0.12 * 63 = +7.6°C. Operation at elevated ambient temperatures is easily supported given this very low internal rise to junction. e0 = The maximum internal junction temperatures would occur at maximum supply voltage, +85°C maximum ambient operating, and where the QFN exposed pad is not tied to a conductive layer. Where the QFN must be mounted with an insulating layer to the exposed metal plate, such as in a split supply application, device measurements show an increased thermal impedance junction to ambient of +120°C/W. Using this, and a maximum quiescent internal power on 4.5V absolute maximum, which shows 45mA for +85°C maximum operating ambient from Figure 27, we get 4.5V * 45mA * +120°C/W = +24°C rise above +85°C or approximately +109°C operating TJ maximum - still well below the specified Absolute Maximum operating junction temperature of +135°C. Noise Analysis The decompensated voltage feedback design of the ISL55210 provides very low input voltage and current noise. While a detailed noise model using arbitrary external resistors can be made, most applications will have a balanced feedback network with the two RF (feedback) resistors equal and the two RG (gain) resistors equal. Figure 33 shows the test circuit used to measure the output noise with the noise terms detailed. The aim here was to measure the output noise with two different resistor settings to extract out a model for the input referred En and In terms for just the amplifier itself. 4kTRf * RF 4kTRg * + 25 in 1:1 * ISL55210 in 4kTRg * ADT1-1WT eO * 25 RG 2 (EQ. 1) The NG term in Equation 1 is the Noise Gain = 1 + RF/RG. The last term in Equation 1 captures both the RF and RG resistor noise terms. If we assume a 50Ω source in Test Circuit #1, the total RG resistor value will be 100Ω as that 50Ω will come through the transformer to look like a 50Ω source on each side. This gives a lower noise gain (3V/V) than signal gain (4V/V) for just the amplifier. The total gain in Test Circuit #1 is still approximately 1.4 * 4 = 5.6V/V including the transformer step up. Putting in NG = 3, RF = 200Ω, RG = 100Ω with the ISL55210 noise terms of eni = 0.85nV/√Hz and In = 5pA/√Hz into Equation 1 (4kT = 1.6E - 20J) gives a total output differential noise voltage = 5.26nV/√Hz. Input referring this to the input side of the transformer of Test Circuit #1 gives an input referred spot noise of only 0.88nV/√Hz. This extremely low input referred noise is a combination of low amplifier noise terms and the effect of the input transformer configuration. Driving Cap and Filter Loads Most applications will drive a resistive or filter load. The ISL55210 is robust to direct capacitive load on the outputs up to approximately 10pF. For frequency response flatness, it is best to avoid any output pin capacitance as much as possible - as that capacitance increases, the high frequency portion of the ISL55210 (>1GHz) response will start to show considerable peaking. No oscillations were observed up through 10pF load on each output. For AC coupled applications, an output network that is a small series resistor (10Ω to 50Ω) into a blocking cap is preferred. This series resistor will isolate parasitic capacitance to ground from the internally closed loop output stage of the amplifier and de-queue the self resonance of the blocking capacitors. Once the output stage sees this resistive element first, the remaining part of the filter design can be done without fear of amplifier instability. Driving ADCs eni RG 1µF 2 ( e ni • NG ) + 2 ( i n R f ) + 2 ( 4kTR f NG ) - 1µF * RF 4kTRf FIGURE 33. NOISE MODEL AND TEST CIRCUIT 1µF 50 Many of the intended applications for the ISL55210 are as a low power, very high dynamic range, last stage interface to high performance ADCs. The lowest power ADCs, such as the ISLA112P50 shown on the front page, include an innovative "Femto-Charge" internal architecture that eliminates op amps from the ADC design and only passes signal charge from stage to stage. This greatly reduces the required quiescent power for these ADCs but then that signal charge has to be provided by the external circuit at the two input pins. This appears on an ADC like the ISLA112P50 as a clock rate dependent common mode input current that must be supplied by the interface circuit. At 500MHz, this DC current is 1.3mA on each input for the ISLA112P50. Most interfaces will also include an interstage noise power bandlimiting filter between the amplifier and the ADC. This filter needs to be designed considering the loading of the amplifier, 14 FN7811.2 June 6, 2013 ISL55210 any VCM level shifting that needs to take place, the filter shape, and this ICM issue into the ADC input pins. Here are 4 example topologies suitable for different situations. 1. AC coupled, broadband RLC interstage filter design. This approach lets the amplifier operate at its desired output common mode, then provides the ADC common mode voltage and current through a bias path as part of the filter design’s last stage R values. The VB is set to include the IR loss from that voltage to the ADC inputs due to the ICM current. This circuit is the one shown on the front page where we get a usable frequency range from about 500kHz to 150MHz. 2. AC coupled, higher frequency range interstage filter design. This design replaces the Rt resistors in Figure 34 with large valued inductors and implements the filter just using shunt resistors at the end of the RLC filter (here, that is just the ADC internal differential Rin). In this case, the ADC VCM can be tied to the centerpoint of the bias path inductors (very much like a Bias-T) to provide the common mode voltage and current to the ADC inputs. These bias inductors do limit the low frequency end of the operation where, with 1µH values, operation from 10MHz to 200MHz is supported using the approach of Figure 35. 3. AC coupled with output side transformer. This design includes an output side transformer, very similar to ADC characterization circuits. This approach allows a slightly lower amplifier output swing (if N > 1 is used) and very easy 2nd order low pass responses to be implemented. It also provides the ICM and VCM bias to the ADC through the transformer centertap. This approach would be attractive for higher ADC input swing targets and more aggressive noise power bandwidth control needs. 4. DC coupled with ADC VCM and ICM provided from the amplifier. Here, DC to very high frequency interstage low pass filters can be provided. Again, the RS element must be low to reduce the IR drop from the VCM of the converter, which now shows up on the output of the ISL55210, to the ADC input pins. In this case, split supplies are required to satisfy the amplifier output and input common mode range limits discussed earlier. Rf RF ADC +3.3V ISL55210 Vcm1 Ls Icm ADC +3.3V IN+ Cb Rs ISL55210 Rt 1.2V Ci n Rin LP VCM1 IN+ 1.2V Ct Cin Rin RT Cb Rt Ls Ct Cb RS Icm R R>t R> R s t s v –V I − I × R × =R V= V B bcm cm t t cm2 cm LP LS INRf ICM Cb RS Ct Vb Rs LS Ct IN- Vcm2 = 0.535 or 1V RF VCM2 = 0.535 or 1V ICM 2 Lp>>Ls FIGURE 34. AC COUPLED, BROADBAND RLC INTERSTAGE FILTER DE SIGN FIGURE 35. AC COUPLED, HIGHER FREQUENCY RLC FILTER DESIGN Rf RF ADC ADC +3.3V ISL55210 VCM1 +3.0V ICM RS Cb ISL55210 1:n Cin Ct Rs Ct RF VCM2 = 0.535 or 1V Rt ≤30Ω 2ICM FIGURE 36. AC COUPLED WITH OUTPUT SIDE TRANSFORMER 15 Ct Ls -1.1V INICM Cin Rin Rt Cb Rt IN+ Ct Vcm Rin RS Icm Rs Rt 1.2V Ls IN+ IN- Rf Icm Rs ≤30Ω Vcm = 0.535V or 1V FIGURE 37. DC COUPLED WITH A COMMON VCM VOLTAGE FROM THE ADC FN7811.2 June 6, 2013 ISL55210 Layout Considerations The ISL55210 pinout is organized to isolate signal I/O along one axis of the package with ground, power and control pins on the other axis. Ground and power should be planes coming into the upper and lower sides of the package (see the Pin Configuration on page 2). The signal I/O should be laid out as tight as possible with parasitic C to the ground and/or power planes reduced as much as possible by opening up those planes under the I/O elements. The ground pins and package backside metal contact should be connected into a good ground plane. The power supply should have both a large value electrolytic cap to ground, then a high frequency ferrite beads, then 0.01µF SMD ceramic caps at the supply pins. Some improvement in HD2 performance may be experienced by placing and X2Y cap between the two VS+ pins and ground underneath the package on the board back side. This is 4 terminal device that is included in the EVM board layout. EVM Board (Rev. C) Test circuit #1 (Figure 28) is implemented on an Evaluation Module Board available from Intersil. This board includes a number of optional features that are not populated as the board is delivered. The full EVM board circuit is shown in Figure 38 where unloaded (optional) elements are shown in green. The nominal supply voltage for the board and device is a single 3.3V supply. From this, the ISL55210, ISL55211 generates an internal common mode voltage of approximately 1.2V. That voltage can be overridden by populating the two resistors and potentiometer shown as R19 to R21 above. The primary test purpose for this board is to implement different interstage differential passive filters intended for the ADC interface along with the ADC input impedances. The board is delivered with only the output R's loaded to give a 200Ω differential load. This is done using the two 85Ω resistors as R9 and R10, then the 4 zero ohm elements (R10, R12, R24, and R25) and finally the two shunt elements R13 and R14 set to 35.5Ω. Including the 50Ω measurement load on the output side of the 1:1 transformer reflecting in parallel with the two 35Ω resistors takes the nominal AC shunt impedance to 71Ω||50Ω = 29.3Ω. This adds to the two 85Ω series output elements to give a total load across the amplifier outputs of 170Ω + 29.3Ω = 199.3Ω. To test a particular ADC interface RLC filter and converter input impedance, replace R11 and R12 with RF chip inductors, load C10 and C11 with the specified ADC input capacitance and R26 with the specified ADC differential input R. With these loaded, the remaining resistive elements (R24, R25, R13, R14) are set to hit a desired total parallel impedance to implement the desired filter (must be < than the ADC input differential R since that sits in parallel with any "external" elements) and achieve a 25Ω source looking into each side of the tap point transformer. This EVM board includes a user's manual showing a number of example circuits and tested results. Available on the Intersil web site in the ISL55210 Product Information Page. Revision History The revision history provided is for informational purposes only and is believed to be accurate, but not warranted. Please go to web to make sure you have the latest revision. DATE REVISION CHANGE June 6, 2013 FN7811.2 Added Related Literature on page 1. Updated Figure “NOISE MODEL AND TEST CIRCUIT” on page 14 that was incorrectly drawn. July 30, 2012 FN7811.1 Added 6th paragraph to section “Power Supply, Shutdown, and Thermal Considerations” on page 13 describing the outputs can not source or sink current during disable mode. March 2, 2011 FN7811.0 Initial Release About Intersil Intersil Corporation is a leader in the design and manufacture of high-performance analog, mixed-signal and power management semiconductors. The company's products address some of the largest markets within the industrial and infrastructure, personal computing and high-end consumer markets. For more information about Intersil, visit our website at www.intersil.com. For the most updated datasheet, application notes, related documentation and related parts, please see the respective product information page found at www.intersil.com. You may report errors or suggestions for improving this datasheet by visiting www.intersil.com/en/support/ask-an-expert.html. Reliability reports are also available from our website at http://www.intersil.com/en/support/qualandreliability.html#reliability For additional products, see www.intersil.com/en/products.html Intersil products are manufactured, assembled and tested utilizing ISO9000 quality systems as noted in the quality certifications found at www.intersil.com/en/support/qualandreliability.html Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design, software and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries. For information regarding Intersil Corporation and its products, see www.intersil.com 16 FN7811.2 June 6, 2013 C1001 4.7µF GND R21 VCC L1 +Vs + BEAD C1002 1.0µF C3 200Ω/DNP 100nF R19 1k/DNP C2 100nF R18 R17 17 Cterm2 2.2pF R8 200Ω 4 13 14 GND Vcm Vs+ GND Vi- NC 11 Vi+ NC Fb- Vo- 1µF 10 C6 9 GND R7 0Ω 12 TEST POINT R20 200Ω/DNP C10 DNP 1µF R11 R24 0Ω 0Ω R13 35.5Ω 0Ω/DNP R14 35.5Ω R10 R12 R25 85Ω 0Ω 0Ω 50Ω C5 100nF TP2 DIFPROBE R16 50Ω 1 PD R22 50Ω 2 3 NC VCC 5 A GND Y C8 ADT1-1WT R28 R15 C4 100nF R9 85Ω ISL55210, ISL55211 8 50Ω R26 DNP TP1 4 74AHC1G04 FIGURE 38. SCHEMATIC FOR ISL55210, ISL55211 SINGLE INPUT TRANSFORMER EVM REV. C OUT 1µF R27 0Ω ISL55210 R2 DNP 2 3 R4 R23 0Ω C9 100nF C7 Vo+ Fb+ PD 50Ω R6 0Ω 1 Vs+ R0 DNP R5 200Ω 7 1µF R3 GND ADT2-1T 50Ω U1 6 C1 Cterm1 2.2pF 5 IN R1 DNP 15 16 200Ω C11 DNP FN7811.2 June 6, 2013 ISL55210 Package Outline Drawing L16.3x3D 16 LEAD THIN QUAD FLAT NO-LEAD PLASTIC PACKAGE Rev 0, 3/10 4X 1.50 3.00 A 12X 0.50 B 13 6 PIN 1 INDEX AREA 16 6 PIN #1 INDEX AREA 12 3.00 1 1.60 SQ 4 9 (4X) 0.15 0.10 M C A B 5 8 16X 0.40±0.10 TOP VIEW 4 16X 0.23 ±0.05 BOTTOM VIEW SEE DETAIL “X” 0.10 C 0.75 ±0.05 C 0.08 C SIDE VIEW (12X 0.50) (2.80 TYP) ( 1.60) (16X 0.23) C 0 . 2 REF 5 0 . 02 NOM. 0 . 05 MAX. (16X 0.60) TYPICAL RECOMMENDED LAND PATTERN DETAIL "X" NOTES: 1. Dimensions are in millimeters. Dimensions in ( ) for Reference Only. 2. Dimensioning and tolerancing conform to ASME Y14.5m-1994. 3. Unless otherwise specified, tolerance : Decimal ± 0.05 4. Dimension applies to the metallized terminal and is measured between 0.15mm and 0.25mm from the terminal tip. 5. Tiebar shown (if present) is a non-functional feature. 6. The configuration of the pin #1 identifier is optional, but must be located within the zone indicated. The pin #1 identifier may be 7. JEDEC reference drawing: MO-220 WEED. either a mold or mark feature. 18 FN7811.2 June 6, 2013