ANALOG DEVICES ADA4862-3 High Speed G = +2 Low Cost Triple Op Amp handbook
Contents
1. 05600 023 10 100 1000 FREQUENCY MHz Figure 20 Large Signal Crosstalk 05600 046 19 T E 18 E z ul tc tc 3 gt 17 E n a 2 o E 5 16 g 15 4 5 6 7 8 9 10 11 12 SUPPLY VOLTAGE V Figure 21 Total Supply Current vs Vsuep y TOTAL SUPPLY CURRENT mA 40 25 10 5 20 35 50 65 80 95 110 125 TEMPERATURE C Figure 22 Total Supply Current at Various Supplies vs Temperature POWER SUPPLY REJECTION dB 05600 026 POWER SUPPLY REJECTION dB 05600 021 Rev A Page 9 of 16 ADA4862 3 05600 051 FREQUENCY MHz Figure 23 Power Supply Rejection vs Frequency 05600 052 FREQUENCY MHz Figure 24 Power Supply Rejection vs Frequency ADA4862 3 DISTORTION dBc DISTORTION dBc 60 80 100 G 2 fo 20MHz Ry 1500 fo 10MHz C 4pF 2 HD2 Vg 5V fo 5MHz fo 2MHz fo 1MHz 2 3 OUTPUT VOLTAGE V p p Figure 25 HD2 vs Frequency vs Output Voltage OUTPUT VOLTAGE V p p Figure 26 HD2 vs Frequency vs Output Voltage DISTORTION dBc 05600 049 DISTORTION dBc 05600 050 Rev A Page 10 of 162. 1000 FREQUENCY MHz Figure 6 Large Signal 0 1 dB Bandwidth for Various Supplies 200 Figure 8 Small Signal Transient Response for Various Capacitor Loads 2 7 2 6 E ul 4 e 9 25 9 i 2 a 5 o G 2 2 4 R 1500 Vour 0 2V p p Vs 5V TIME 5ns DIV 05600 022 05600 014 23 Figure 9 Small Signal Transient Response for Various Capacitor Loads Rev A Page 6 of 16 Vg 5V Mg OV 05600 028 OUTPUT VOLTAGE V OUTPUT VOLTAGE V OUTPUT VOLTAGE V 1 0 G 42 RL 1500 CL 4pF Vout 2V p p TIME 5ns DIV G 2 RL 1500 C 4pF Vout 2V p p Vg 25V TIME 5ns DIV G 2 RL 1500 C 4pF Vout 2V p p Vs 5V TIME 5ns DIV 0V OUTPUT VOLTAGE V Vs 5V Vs OUTPUT AND INPUT VOLTAGE V 05600 010 OUTPUT AND INPUT VOLTAGE V 05600 018 05600 019 Figure 12 Large Signal Transient Response for Various Capacitor Loads Rev A Page 7 of 16 ADA4862 3 INPUT VOLTAGE s 05600 042 0 100 200 300 400 500 600 700 800 900 1000 TIME ns Figure 13 Input Overdrive Recovery hat INPUT VOLTAGE 05600 041 0 100 200 300 400 500 600 700 800 900 1000 TIME ns Figure 14 Output
3. 05600 008 0 1 1 10 100 1000 FREQUENCY MHz Figure 41 Large Signal Frequency Response for Various Supplies Ri 75 Q ADA4862 3 SINGLE SUPPLY OPERATION The ADA4862 3 can also operate in single supply applications Figure 42 shows the schematic for a single 5 V supply video driver Resistors R2 and R4 establish the midsupply reference Capacitor C2 is the bypass capacitor for the midsupply reference Capacitor C1 is the input coupling capacitor and C6 is the output coupling capacitor Capacitor C5 prevents constant current from being drawn through the internal gain set resistor Resistor R3 sets the circuits ac input impedance For more information on single supply operation of op amps see www analog com library analogDialogue archives 35 02 avoiding 5V Vin R1 C1 500 22uF Vour 05600 035 Figure 42 Single Supply Video Driver Schematic POWER DOWN The ADA4862 3 is equipped with an independent Power Down pin for each amplifier allowing the user to reduce the supply current when an amplifier is inactive The voltage applied to the Vs pin is the logic reference making single supply applications useful with conventional logic levels In a typical 5 V single supply application the Vs pin is connected to analog ground The amplifiers are powered down when applied logic levels are greater than Vs 1 V The amplifiers are enabled whenever the disable pins are left either floating discon
4. 1 which E are discussed next 21 i i 308 ded Unity Gain O tion Option 1 FREQUENCY MHz nity Gain eration ion y p p Figure 32 Large Signal Gain 1 There are two options for obtaining unity gain G 1 The first is shown in Figure 30 In this configuration the IN input pin is left floating feedback is provided via the internal 550 Q and the input is applied to the noninverting input The noise gain for this configuration is 1 Frequency performance and gt transient response are shown in Figure 31 through Figure 33 5 a jarj o gt 2 n 5 G 1 S RL 1500 Vout 2V p p Vg 25V TIME 5ns DIV g Figure 33 Large Signal Transient Response for Various Capacitor Loads 05600 032 GAIN OF 1 Figure 30 Unity Gain of Option 1 Rev A Page 11 of 16 ADA4862 3 200 Option 2 G 1 1 Another option exists for running the ADA4862 3 as a unity 150 E RE E dnd gain amplifier In this configuration the noise gain is 2 see Lo OF ln n l E Figure 34 The frequency response and transient response for E f this configuration closely match the gain of 2 plots because the 9 sor t noise gains are equal This method does have twice the noise d ok NR TRIER gain of Option 1 however in applications that do not require E I low noise Option 2 offers less peaking and ringing By tying the a m i inputs together the net gain of the amplifier become
5. 3 0 5 mA Power Supply Rejection Ratio RTO dB PSR Vs 4V to 6 V Vs 5 V 54 57 dB PSR TVs 2 5V Vs 4 V to 6V 450 5 54 dB Power Down pin Vs Rev A Page 4 of 16 ABSOLUTE MAXIMUM RATINGS Table 3 Parameter Rating Supply Voltage 12 6V Power Dissipation See Figure 3 Common Mode Input Voltage Vs Storage Temperature 65 C to 125 C Operating Temperature Range 40 C to 105 C Lead Temperature JEDEC J STD 20 Junction Temperature 150 C Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device This is a stress rating only functional operation of the device at these or any other conditions above those indicated in the operational section of this specification is not implied Exposure to absolute maximum rating conditions for extended periods may affect device reliability THERMAL RESISTANCE Ora is specified for the worst case conditions that is Oya is specified for device soldered in circuit board for surface mount packages Table 4 Thermal Resistance Package Type Osa Unit 14 lead SOIC 90 C W Maximum Power Dissipation The maximum safe power dissipation for the ADA4862 3 is limited by the associated rise in junction temperature T on the die At approximately 150 C which is the glass transition temperature the plastic changes its properties Even temporarily exceeding this temperature limit
6. MHZ Vo 2 V p p 76 dBc Voltage Noise RTO f 100 kHz 10 6 nV VHz Current Noise RTI f 100 kHz IN 14 pA VHz Differential Gain 0 02 Differential Phase 0 03 Degrees Crosstalk Amplifier 1 driven Amplifier 2 output 75 dB measured f 1 MHz DC PERFORMANCE Offset Voltage RTO Referred to output RTO 25 43 5 25 mV Input Bias Current 25 0 6 HA Gain Accuracy 1 9 2 2 1 V V INPUT CHARACTERISTICS Input Resistance IN 13 MO Input Capacitance N 2 pF Input Common Mode Voltage Range G 1 1to4 V POWER DOWN PIN Input Voltage Enabled 0 6 V Power down 1 8 V Bias Current Enabled 3 HA Power down 115 HA Turn On Time 3 5 us Turn Off Time 200 ns OUTPUT CHARACTERISTICS Output Overdrive Recovery Time Rise Fall Vin 2 25 V to 0 25 V 85 50 ns Output Voltage Swing R 21500 1 2to 3 8 V Output Voltage Swing Ri 1kOQ 1to4 V Short Circuit Current Sinking or sourcing 65 mA POWER SUPPLY Operating Range 5 12 V Total Quiescent Current Enabled 14 16 18 mA Quiescent Current Amplifier Power down 4 Vs 0 2 0 33 mA Power Supply Rejection Ratio RTO dB PSR Vs 2 V to 3V Vs 2 5V 52 55 dB PSR 4 Vs 2 5 V Vs 2 V to 3 V 49 52 dB Power Down pin Vs Rev A Page 3 of 16 ADA4862 3 Vs 5 V OTA 25 C G 2 Rt 150 Q unless otherwise noted Table 2 Parameter Conditions Min Typ Max Unit DYNAMIC PERFORMANCE 3 dB Bandwidth Vo 0 2 V p p 310 MHz Vo 2 V p p 26
7. fo 20MHz fo 10MHz OUTPUT VOLTAGE V p p Figure 27 HD3 vs Frequency vs Output Voltage fo 10MHz 0 0 5 1 0 OUTPUT VOLTAGE V p p Figure 28 HD3 vs Frequency vs Output Voltage 1 5 05600 054 05600 048 ADA4862 3 APPLICATIONS USING THE ADA4862 3 IN GAINS 1 1 mae The ADA4862 3 was designed to offer outstanding video 3 a E iF Vs 5V performance simplify applications and minimize board area _ a PR m 2 The ADA4862 3 is a triple amplifier with on chip feedback and E 1 gain set resistors The gain is fixed internally at G 2 The s Vg 5V inclusion of the on chip resistors not only simplifies the design 9 of the application but also eliminates six surface mount 2 E resistors saving valuable board space and lowers assembly 9 costs A typical schematic is shown in Figure 29 E gt Vs 3 g 4 8 0 1 1 10 100 1000 FREQUENCY MHz Figure 31 Small Signal Unity Gain m 2 z q o n o g o GAIN OF 2 3 a E D 2 o Figure 29 Noninverting Configuration G 4 2 d While the ADA4862 3 has a fixed gain of G 2 it can be used a in other gain configurations such as G 1 and G
8. may change the stresses that the package exerts on the die permanently shifting the parametric performance of the amplifiers Exceeding a junction temperature of 150 C for an extended period can result in changes in silicon devices potentially causing degradation or loss of functionality ESD CAUTION ESD electrostatic discharge sensitive device Electrostatic charges as high as 4000 V readily accumulate on ADA4862 3 The power dissipated in the package Pp is the sum of the quiescent power dissipation and the power dissipated in the die due to the amplifier s drive at the output The quiescent power is the voltage between the supply pins Vs x the quiescent current Is Pp Quiescent Power Total Drive Power Load Power RMS output voltages should be considered Airflow increases heat dissipation effectively reducing Oya In addition more metal directly in contact with the package leads and through holes under the device reduces Oya Figure 3 shows the maximum safe power dissipation in the package vs the ambient temperature for the 14 lead SOIC 90 C W on a JEDEC standard 4 layer board Oja values are approximations 2 5 2 0 o E a a 2 1 5 a tc o 1 0 n z 2 E 0 5 o 55 45 35 25 15 5 5 15 25 35 45 55 65 75 85 95 105 115 125 AMBIENT TEMPERATURE C Figure 3 Maximum Power Dissipation vs Temperature for a 4 Layer
9. to each of the power supply pins as is physically possible no more than 1 8 inch away The ground returns should terminate immediately into the ground plane Locating the bypass capacitor return close to the load return minimizes ground loops and improves performance Rev A Page 14 of 16 ADA4862 3 OUTLINE DIMENSIONS 8 75 0 3445 8 55 103366 i 4 00 0 1575 3 80 0 1496 6 20 0 2441 5 80 0 2283 1 27 0 0500 0 50 0 0197 1 75 0 0689 99010 0197 BSC 1 75 0 0689 0 25 0 0098 1 35 0 0531 I 0 25 0 0098 0 10 0 0039 23 TY me OX Hel pe COPLANARITY OST D DID SEATING 0 25 0 0098 9 1 27 0 0500 0 10 31 0 0 17 0 0067 0 40 0 0157 COMPLIANT TO JEDEC STANDARDS MS 012 AB CONTROLLING DIMENSIONS ARE IN MILLIMETERS INCH DIMENSIONS IN PARENTHESES ARE ROUNDED OFF MILLIMETER EQUIVALENTS FOR REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN Figure 43 14 Lead Standard Small Outline Package SOIC NI Narrow Body R 14 Dimensions shown in millimeters and inches ORDERING GUIDE Model Temperature Range Package Description Ordering Quantity Package Option ADA4862 3YRZ 40 C to 105 C 14 Lead SOIC_N 1 R 14 ADA4862 3YRZ RL 40 C to 105 C 14 Lead SOIC_N 2 500 R 14 ADA4862 3YRZ RL7 40 C to 105 C 14 Lead SOIC_N 1 000 R 14 Z Pb free part Rev A Page 15 of 16 ADA4862 3 NOTES 2005 Analog Devices Inc All rights r
10. 0 0 ADA4862 3 0 ANALOG High Speed G 2 DEVICES Low Cost Triple Op Amp ADA4862 3 FEATURES PIN CONFIGURATION Ideal for RGB HD SD video Supports 1080i 720p resolution High speed 3 dB bandwidth 300 MHz Slew rate 750 V us Settling time 9 ns 0 596 0 1 dB flatness 65 MHz Differential gain 0 0296 Differential phase 0 03 Wide supply range 5 V to 12V Low power 5 3 mA amp Low voltage offset RTO 3 5 mV typ High output current 25 mA Figure 1 14 Lead SOIC R 14 Also configurable for gains of 1 1 Power down 05600 001 APPLICATIONS Consumer video Professional video Filter buffers GENERAL DESCRIPTION The ADA4862 3 triple is a low cost high speed internally The ADA4862 3 is available in a 14 lead SOIC package and is fixed G 2 op amp which provides excellent overall designed to work in the extended temperature range of 40 C performance for high definition and RGB video applications to 105 C The 300 MHz G 2 3 dB bandwidth and 750 V us slew rate make this amplifier well suited for many high speed applications The ADA4862 3 can also be configured to operate in gains of G 1 and G 1 With its combination of low price excellent differential gain n 0 0296 differential phase 0 03 and 0 1 dB flatness out to 8 65 MHz this amplifier is ideal for both consumer and z prof
11. 0 MHz G 1 Vo 0 2 V p p 720 MHz Bandwidth for 0 1 dB Flatness Vo 2 V p p 54 MHz Slew Rate Rising Edge Vo 2 V p p 1050 V us Slew Rate Falling Edge Vo 2V p p 830 V us Settling Time to 0 596 Vo 2Vstep 9 ns DISTORTION NOISE PERFORMANCE Harmonic Distortion HD2 fc 1 MHz Vo 2 V p p 87 dBc Harmonic Distortion HD3 fc 1 MHz Vo 2V p p 100 dBc Harmonic Distortion HD2 fc 5 MHz Vo 2 V p p 74 dBc Harmonic Distortion HD3 fc 5 MHz Vo 2 V p p 90 dBc Voltage Noise RTO f 100 kHz 10 6 nV VHz Current Noise RTI f 100 kHz IN 14 pA VHz Differential Gain 0 01 Differential Phase 0 02 Degrees Crosstalk Amplifier 1 driven Amplifier 2 output 75 dB measured f 1 MHz DC PERFORMANCE Offset Voltage RTO 25 2 25 mV Input Bias Current 2 5 0 6 1 HA Gain Accuracy 1 9 2 2 1 V V INPUT CHARACTERISTICS Input Resistance IN 14 MQ Input Capacitance IN 2 pF Input Common Mode Voltage Range G 1 3 to 3 8 V POWER DOWN PIN Input Voltage Enabled 44 V Power down 3 2 V Bias Current Enabled 3 HA Power down 250 HA Turn On Time 3 5 us Turn Off Time 200 ns OUTPUT CHARACTERISTICS Output Overdrive Recovery Time Rise Fall Vin 3 0V 85 40 ns Output Voltage Swing R 21500 3 5 to 43 5 V Output Voltage Swing R 1kQ 3 9 to 3 9 V Short Circuit Current Sinking or sourcing 115 mA POWER SUPPLY Operating Range 5 12 V Total Quiescent Current Enabled 14 5 17 9 205 mA Quiescent Current Amplifier Power down 4 Vs 0
12. Board the human body and test equipment and can discharge without detection Although this product features FART Te S proprietary ESD protection circuitry permanent damage may occur on devices subjected to high energy Spr Ate electrostatic discharges Therefore proper ESD precautions are recommended to avoid performance degradation or loss of functionality ESD SENSITIVE DEVICE Rev A Page 5 of 16 ADA4862 3 TYPICAL PERFORMANCE CHARACTERISTICS CLOSED LOOP GAIN dB CLOSED LOOP GAIN dB CLOSED LOOP GAIN dB 8 G 2 RL 1500 200 7 FCL 4pF Vout 0 2V p p Vs 5V 6 c 100 5 t Vs 225V ul u 4 os ES a an 0 o On gt 3 gt gt EA 5 2 a a E 2 E 2 o G 2 o 100 RL 1500 1 5 C 4pF S Vout 0 2V p p 0 8 TIME 5ns DIV 0 1 1 10 100 1000 200 FREQUENCY MHz Figure 4 Small Signal Frequency Response for Various Supplies Figure 7 Small Signal Transient Response for Various Supplies G 42 RL 1500 CL 4pF Vout 2V p p Lu o lt jarj 9 C 6pF E 2 n E a G 42 100 RL 1500 a C 4pF 3 Vout 0 2V p p 150 Vg 25V 2 0 TIME 5ns DIV E FREQUENCY MHz Figure 5 Large Signal Frequency Response for Various Supplies 6 1
13. Overdrive Recovery ADA4862 3 Vout AND Vin V SLEW RATE V us VOLTAGE NOISE nVAHz 100 10 1 Vour EXPANDED Vour EXPANDED mV 20 25 30 35 40 45 50 TIME ns Figure 18 Settling Time Rising Edge POSITIVE SLEW RATE NEGATIVE SLEW RATE Vs 5V 5V G 2 Vout 2V p p RL 1500 C 4pF s Vour E S EXPANDED a z u gt a 2 2 amp E 5 5 gt o gt 3 TIME ns Figure 15 Settling Time Falling Edge ITIVE SLEW T NEGATIVE SLEW RATE E W a o 0 05 1 0 15 20 25 30 35 40 45 5 0 OUTPUT VOLTAGE STEP V p p Figure 16 Slew Rate vs Output Voltage G 2 RL 1500 CL 4pF Vout 2V p p Vg 5V Vs 5V CROSSTALK dB 05600 037 10 100 1k 10k 100k 1M 10M 100M Figure FREQUENCY Hz 17 Voltage Noise vs Frequency Referred to Output RTO Rev A Page 8 of 16 05600 006 1 0 1 5 2 0 2 5 3 0 OUTPUT VOLTAGE STEP V p p Figure 19 Slew Rate vs Output Voltage G 2 RL 1500 C 4pF Vout 2V p p Vg 5V Vg 5V b eo 1 eo eo 100 120 0 1 1
14. eserved Trademarks and ANALOG registered trademarks are the property of their respective owners D05600 0 8 05 A DEVICES www analo g com Rev A Page 16 of 16 HRA WWW ZFA CN ERRA NIPDFAX PR Ph WWW Z a cn CA ARALARA PATI XICPIEO41662 3 Ol gl Az HR XA ER XYI 0755 83278916 83278919 ALEC 010 62632888 62636888
15. essional video applications d The ADA4862 3 is designed to operate on supply voltages as P low as 5 V and up to 5 V using only 5 3 mA amp of supply d current To further reduce power consumption each amplifier is equipped with a power down feature that lowers the supply 3 current to 200 uA amp The ADA4862 3 also consumes less E board area because feedback and gain set resistors are on chip 0 Having the resistors on chip simplifies layout and minimizes the FREQUENCY MHz required board space Figure 2 Large Signal 0 1 dB Bandwidth for Various Supplies Rev A Information furnished by Analog Devices is believed to be accurate and reliable However no responsibility is assumed by Analog Devices for its use nor for any infringements of patents or other rights of third parties that may result fromits use Specifications subject to change without notice No One Technology Way P O Box 9106 Norwood MA 02062 9106 U S A license is granted by implication or otherwise under any patent or patent rights of Analog Devices Tel 781 329 4700 www analog com Trademarks and registered trademarks are the property of their respective owners Fax 781 461 3113 2005 Analog Devices Inc All rights reserved ADA4862 3 TABLE OF CONTENTS iunc ln 1 ADDIICAEIOTIS szt en tete 11 Applications siet otto ttt e RP ER ER ies 1 Using the ADA4862 3 in Gains 1 1 11 Pini Configuration oett mtem tere d 1 Video Lire DEVER sa
16. nected or the applied logic levels are lower than 1 V above Vs Rev A Page 13 of 16 ADA4862 3 LAYOUT CONSIDERATIONS As is the case with all high speed applications careful attention to printed circuit board layout details prevents associated board parasitics from becoming problematic Proper RF design technique is mandatory The PCB should have a ground plane covering all unused portions of the component side of the board to provide a low impedance return path Removing the ground plane on all layers from the area near the input and output pins reduces stray capacitance Termination resistors and loads should be located as close as possible to their respective inputs and outputs Input and output traces should be kept as far apart as possible to minimize coupling crosstalk though the board Adherence to microstrip or stripline design techniques for long signal traces greater than about 1 inch is recommended POWER SUPPLY BYPASSING Careful attention must be paid to bypassing the power supply pins of the ADA4862 3 High quality capacitors with low equivalent series resistance ESR such as multilayer ceramic capacitors MLCCs should be used to minimize supply voltage ripple and power dissipation A large usually tantalum 10 uF to 47 uF capacitor located in proximity to the ADA4862 3 is required to provide good decoupling for lower frequency signals In addition 0 1 uF MLCC decoupling capacitors should be located as close
17. s 1 D cog Equation 1 shows the transfer characteristic for the schematic i shown in Figure 34 Frequency and transient response are AE 8 shown in Figure 35 and Figure 36 200 1 Figure 36 Small Signals Transient Response of Option 2 Vs Vs 05600 031 GAIN OF 1 Figure 37 Inverting Configuration G 1 Vs 8 GAIN OF 1 8 Figure 34 Unity Gain of Option 2 1 Lu 0 o lt G 1 jarj 1 HRL 1500 9 2 2 a 5 Gz 1 kJ o RL 1500 z 5 Vour 2Vpp S Vs 5V 4 i TIME 5ns DIV N 6 Figure 38 Large Signal Transient Response for Various Capacitor Loads E 8 0 1 1 10 100 1000 FREQUENCY MHz Figure 35 Frequency Response of Option 2 Rev A Page 12 of 16 VIDEO LINE DRIVER The ADA4862 3 was designed to excel in video driver applications Figure 39 shows a typical schematic for a video driver operating on a bipolar supplies Vs B 10uF e IDE 750 Viv o7 4 E 05600 033 Figure 39 Video Driver Schematic In applications that require two video loads be driven simultaneously the ADA4862 3 can deliver Figure 40 shows the ADA4862 3 configured with dual video loads Figure 41 shows the dual video load performance 750 10uF 750 CABLE Vs 05600 034 CLOSED LOOP GAIN dB
18. s docete etd 13 General Description terae e 1 Single Supply Operation sse 13 piod opcao R elli tests paia pontua eee 2 Power DOW sets E Ta toD om E 13 Specifications sia e ime ee E oras mascar a elle 3 Layout Considerations eene 14 Absolute Maximum Ratings esee 5 Power Supply Bypassing eene 14 Thermal Resistance eee tie tor reri ka 5 Outline Dimensions niet iret iiaiai 15 ESD Ca tioTi cei iet tie ii s Rte EM an 5 Ordering Guide ciere tere tete iae 15 Typical Performance Characteristics sss 6 REVISION HISTORY 8 05 Rev 0 to Rev A Changes to Ordering Guide eee 15 7 05 Revision 0 Initial Version Rev A Page 2 of 16 SPECIFICATIONS Vs 5 V OTA 25 C G 2 Rr 150 0 unless otherwise noted ADA4862 3 Table 1 Parameter Conditions Min Typ Max Unit DYNAMIC PERFORMANCE 3 dB Bandwidth Vo 0 2 V p p 300 MHz Vo 2 V p p 200 MHz G 1 Vo 0 2 V p p 620 MHz Bandwidth for 0 1 dB Flatness Vo 2 V p p 65 MHz Slew Rate Rising Edge Vo 2Vp p 750 V us Slew Rate Falling Edge Vo 2 V p p 600 V us Settling Time to 0 596 Vo 2 V step 9 ns DISTORTION NOISE PERFORMANCE Harmonic Distortion HD2 fc 1 MHZ Vo 2 V p p 81 dBc Harmonic Distortion HD3 fc 1 MHz Vo 2 V p p 88 dBc Harmonic Distortion HD2 fc 5 MHz Vo 2 V p p 68 dBc Harmonic Distortion HD3 fc 5
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