Op Amps for Everyone - The Repeater Builder's Technical ...

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Comparison of Compensation Schemes V TH V IN R 1 Cs R R G 1 Cs R G R 1 Cs R TH R R G 1 Cs (7–24) V OUT V TH R F (7–25) R TH (7–26) V OUT V IN R 1 Cs R R G 1 Cs R F R G R 1 Cs R F R G RR G 1 Cs Equation 7–26 is intuitively obvious because the RC network is placed across a virtual ground. As long as the loop gain, Aβ, is large, the feedback will null out the closed-loop effect of RC, and the circuit will function as if it were not there. The closed-loop log plot of the lead-lag-compensated op amp is given in Figure 7–22. Notice that the pole and zero resulting from the compensation occur and are gone before the first amplifier poles come on the scene. This prevents interaction, but it is not required for stability. 1/RC 20 Log A Amplitude 20 Log R F R G 1/(R G + R)C 1/τ 1 1/τ 2 Log(f) Figure 7–22. Closed-Loop Plot of Lead-Lag Compensated Op Amp 7.9 Comparison of Compensation Schemes Internally compensated op amps can, and often do, oscillate under some circuit conditions. Internally compensated op amps need an external pole to get the oscillation or ringing started, and circuit stray capacitances often supply the phase shift required for instability. Loads, such as cables, often cause internally compensated op amps to ring severely. 7-20
Conclusions Dominant pole compensation is often used in IC design because it is easy to implement. It rolls off the closed-loop gain early; thus, it is seldom used as an external form of compensation unless filtering is required. Load capacitance, depending on its pole location, usually causes the op amp to ring. Large load capacitance can stabilize the op amp because it acts as dominant pole compensation. The simplest form of compensation is gain compensation. High closed-loop gains are reflected in lower loop gains, and in turn, lower loop gains increase stability. If an op amp circuit can be stabilized by increasing the closed-loop gain, do it. Stray capacitance across the feedback resistor tends to stabilize the op amp because it is a form of lead compensation. This compensation scheme is useful for limiting the circuit bandwidth, but it decreases the closed-loop gain. Stray capacitance on the inverting input works with the parallel combination of the feedback and gain setting resistors to form a pole in the Bode plot, and this pole decreases the circuit’s stability. This effect is normally observed in high-impedance circuits built with CMOS op amps. Adding a feedback capacitor forms a compensated attenuator scheme that cancels out the input pole. The cancellation occurs when the input and feedback RC time constants are equal. Under the conditions of equal time constants, the op amp functions as though the stray input capacitance was not there. An excellent method of implementing a compensated attenuator is to build a stray feedback capacitor using the ground plane and a trace off the output node. Lead-lag compensation stabilizes the op amp, and it yields the best closed-loop frequency performance. Contrary to some published opinions, no compensation scheme will increase the bandwidth beyond that of the op amp. Lead-lag compensation just gives the best bandwidth for the compensation. 7.10 Conclusions The stability criteria often is not oscillation, rather it is circuit performance as exhibited by peaking and ringing. The circuit bandwidth can often be increased by connecting an external capacitor in parallel with the op amp. Some op amps have hooks that enable a parallel capacitor to be connected in parallel with a portion of the input stages. This increases bandwidth because it shunts high frequencies past the low bandwidth g m stages, but this method of compensation depends on the op amp type and manufacturer. The compensation techniques given here are adequate for the majority of applications. When the new and challenging application presents itself, use the procedure outlined here to invent your own compensation technique. Voltage-Feedback Op Amp Compensation 7-21
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Design Reference August 2002 Advanc
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Forward Everyone interested in anal
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Contents Contents 1 The Op Amp’s
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Contents 10 Op Amp Noise Theory and
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Contents 14.4.3 AC Application Erro
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Contents 17.7.1 Through-Hole Consid
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Figures Figures 2-1 Ohm’s Law App
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Figures 7-5 TL08X Frequency and Tim
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Figures 13-12 Differential Amplifie
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Figures 16-41 Comparison of Q Betwe
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Figures A-37 Basic Wien Bridge Osci
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Examples Examples 16-1 First-Order
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Chapter 1 The Op Amp’s Place In T
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The first signal conditioning op am
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Chapter 2 Review of Circuit Theory
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Voltage Divider Rule source, throug
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Thevenin’s Theorem 2.5 Thevenin
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Thevenin’s Theorem V OUT V TH R
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Calculation of a Saturated Transist
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Transistor Amplifier 2 V (from 8 V
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Chapter 3 Development of the Ideal
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The Noninverting Op Amp 3.2 The Non
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The Adder 3-5, and if R F = 100 k a
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Complex Feedback Networks portion o
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Video Amplifiers 3.7 Video Amplifie
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Summary 3.9 Summary When the proper
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Chapter 4 Single-Supply Op Amp Desi
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Circuit Analysis R G R F +V V IN _
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Circuit Analysis V OUT VCC -V IN
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Circuit Analysis R G R F V CC V REF
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Simultaneous Equations m 2 1 0.1
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Simultaneous Equations R F R G R G
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Simultaneous Equations measured 4.5
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Simultaneous Equations +5V R 2 820
Page 69 and 70: Simultaneous Equations |m| 5.56 R
Page 71 and 72: Simultaneous Equations 4.3.4 Case 4
Page 73 and 74: Simultaneous Equations -0.10 -0.15
Page 75 and 76: Chapter 5 Feedback and Stability Th
Page 77 and 78: Block Diagram Math and Manipulation
Page 79 and 80: Block Diagram Math and Manipulation
Page 81 and 82: Bode Analysis of Feedback Circuits
Page 87 and 88: Loop Gain Plots are the Key to Unde
Page 89 and 90: The Second Order Equation and Ringi
Page 91 and 92: Chapter 6 Development of the Non Id
Page 93 and 94: Review of the Canonical Equations T
Page 95 and 96: Noninverting Op Amps 6.3 Noninverti
Page 97 and 98: Inverting Op Amps The transfer equa
Page 99 and 100: Differential Op Amps A aZ G Z G Z
Page 101 and 102: Chapter 7 Voltage-Feedback Op Amp C
Page 103 and 104: Internal Compensation Figure 7-2 sh
Page 105 and 106: Internal Compensation AVD - Large-S
Page 107 and 108: Internal Compensation - Large-Signa
Page 109 and 110: Dominant-Pole Compensation 7.4 Domi
Page 111 and 112: Dominant-Pole Compensation 100 dB D
Page 113 and 114: Lead Compensation Gain compensation
Page 115 and 116: Lead Compensation slopes down at -2
Page 117 and 118: Compensated Attenuator Applied to O
Page 119: Lead-Lag Compensation C R + _ V OUT
Page 123 and 124: Chapter 8 Current-Feedback Op Amp A
Page 125 and 126: The Noninverting CFA output impedan
Page 127 and 128: The Inverting CFA V OUT V IN Z1 Z
Page 129 and 130: Stability Analysis 8.6 Stability An
Page 131 and 132: Selection of the Feedback Resistor
Page 133 and 134: Stability and Input Capacitance Tab
Page 135 and 136: Compensation of CF and CG Z F A R
Page 137 and 138: Chapter 9 Voltage- and Current-Feed
Page 139 and 140: Bandwidth The noninverting input of
Page 141 and 142: Bandwidth The CFA is a current oper
Page 143 and 144: Impedance The CFA stability is not
Page 145 and 146: Equation Comparison Table 9-1. Tabu
Page 147 and 148: Chapter 10 Op Amp Noise Theory and
Page 149 and 150: Characterization 10.2.2 Noise Floor
Page 151 and 152: Types of Noise 10.3.1 Shot Noise Th
Page 153 and 154: Types of Noise as average dc curren
Page 155 and 156: Types of Noise Some characteristics
Page 157 and 158: Noise Colors There are an infinite
Page 159 and 160: Op Amp Noise 1000 Hz V n - Input No
Page 161 and 162: Op Amp Noise can be represented bet
Page 163 and 164: Op Amp Noise This simplifies the ga
Page 165 and 166: Putting It All Together 10.6 Puttin
Page 167 and 168: Putting It All Together When it is
Page 169 and 170: References +5 V 100 k +5 V 100 k V
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Chapter 11 Understanding Op Amp Par
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Operational Amplifier Parameter Glo
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Additional Parameter Information 10
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Additional Parameter Information +V
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Additional Parameter Information of
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Chapter 12 Instrumentation: Sensors
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The system definition specifies the
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pends heavily on test conditions su
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the bias resistor, R 1 , is selecte
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V OUT I D R F (12-6) The phototran
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the semiconductor in a direction pe
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eference has a temperature drift of
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impedance of the transducer. The te
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Y mX b (12-14) Two pairs of data
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Table 12-5. Offset and Gain Error B
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R G 23.7 kΩ R FB 280 kΩ R FA 200
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12.10 Test The final circuit is rea
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Chapter 13 Wireless Communication:
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Wireless Systems ality. Image rejec
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Wireless Systems of the DAC, is usu
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Selection of ADCs/DACs The mean squ
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Selection of ADCs/DACs fication. Wi
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Anti-Aliasing Filters The op amp dy
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Communication D/A Converter Reconst
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External Vref Circuits for ADCs/DAC
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External Vref Circuits for ADCs/DAC
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High-Speed Analog Input Drive Circu
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High-Speed Analog Input Drive Circu
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Chapter 14 Interfacing D/A Converte
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Understanding the D/A Converter and
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Understanding the D/A Converter and
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D/A Converter Error Budget 14.4.1 A
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D/A Converter Error Budget 20 Ampli
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D/A Converter Errors and Parameters
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Increasing Op Amp Buffer Amplifier
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Chapter 15 Sine Wave Oscillators Ro
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Phase Shift in the Oscillator 15.3
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Active Element (Op Amp) Impact on t
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Analysis of the Oscillator Operatio
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Sine Wave Oscillator Circuits Phase
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Sine Wave Oscillator Circuits large
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Sine Wave Oscillator Circuits The i
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Sine Wave Oscillator Circuits R F 1
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Sine Wave Oscillator Circuits V OUT
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Sine Wave Oscillator Circuits resis
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Sine Wave Oscillator Circuits 15.7.
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Chapter 16 Active Filter Design Tec
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Fundamentals of Low-Pass Filters V
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Fundamentals of Low-Pass Filters A(
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Fundamentals of Low-Pass Filters 16
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Fundamentals of Low-Pass Filters 10
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Low-Pass Filter Design The multipli
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Low-Pass Filter Design C 1 R 1 R 2
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Low-Pass Filter Design V IN R 1 R 2
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Low-Pass Filter Design The general
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Low-Pass Filter Design In order to
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High-Pass Filter Design With C 1 =
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High-Pass Filter Design 16.4.1 Firs
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High-Pass Filter Design To simplify
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Band-Pass Filter Design R 1 1 1 2
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Band-Pass Filter Design 16.5.1 Seco
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Band-Pass Filter Design Because of
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Band-Pass Filter Design A mi is
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Band-Pass Filter Design In accordan
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Band-Rejection Filter Design |A| [d
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Band-Rejection Filter Design or to
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All-Pass Filter Design 0 |A| — Ga
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All-Pass Filter Design Inserting th
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All-Pass Filter Design The transfer
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Practical Design Hints 16.8 Practic
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Practical Design Hints +V CC +V CC
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Practical Design Hints The differen
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Practical Design Hints 16.8.4 Op Am
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Filter Coefficient Tables 16.9 Filt
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Filter Coefficient Tables Table 16-
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References 16.10 References D.Johns
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Chapter 17 Circuit Board Layout Tec
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PCB Mechanical Construction 17.2 PC
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PCB Mechanical Construction V+ IN -
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Grounding ponents and feed-throughs
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Grounding components carefully if t
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The Frequency Characteristics of Pa
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Decoupling + Figure 17-15. Logic Ga
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Input and Output Isolation A decoup
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Packages SINGLE DUAL SHORT TRACES L
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Packages and other passive componen
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References 17.8.4 Routing 17.
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Chapter 18 Designing Low-Voltage Op
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Dynamic Range The trick to designin
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Signal-to-Noise Ratio Table 18-1. C
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Input Common-Mode Range Many low vo
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Input Common-Mode Range The input s
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Output Voltage Swing Op amps always
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Single-Supply Circuit Design every
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Transducer to ADC Analog Interface
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DAC to Actuator Analog Interface is
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DAC to Actuator Analog Interface Th
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Comparison of Op Amps Table 18-2. O
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Summary mon-mode range of the op am
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Appendix A Single-Supply Circuit Co
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Introduction + 5 V R G R F +V CC _
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Amplifiers A.3 Amplifiers Many type
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Amplifiers A.3.3 Inverting Op Amp w
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Amplifiers A.3.5 Noninverting Op Am
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Amplifiers A.3.7 Noninverting Op Am
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Amplifiers A.3.9 Differential Ampli
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Amplifiers A.3.11 High Input Impeda
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Amplifiers A.3.13 High-Precision Di
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Amplifiers A.3.15 Variable Gain Dif
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Amplifiers A.3.17 Buffer The buffer
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Amplifiers A.3.19 Noninverting AC A
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Computing Circuits A.4.2 Noninverti
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Computing Circuits A.4.4 Inverting
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Computing Circuits A.4.10 Noninvert
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Oscillators A.5 Oscillators This se
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Oscillators A.5.3 Wien Bridge Oscil
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Oscillators A.5.5 Classical Phase S
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Oscillators A.5.7 Bubba Oscillator
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Appendix BA Single-Supply Op Amp Se
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Table B-1. Single-Supply Operationa
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A AC loads, DAC, 14-2 AC parameters
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low pass filter, 16-1 low-pass filt
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esistor ladder, 14-2 to 14-4 resist
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phase shift for TL07x, 7-5 phase sh
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N Noise, 10-8 to 10-10 avalanche, 1
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packages, 17-24 to 17-27 parallel s
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Theorem Norton’s, 2-5 Superpositi
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