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Increasing Op Amp Buffer Amplifier Current and Voltage 14.7.1 Current Boosters These usually use some variation of the class-B push-pull amplifier topology (Figure 14–16). + 15 V D/A R (bias) NPN VREF D VREF/R RF CF _ DIODE R (small) RIN RS CO + DIODE R (small) VOUT PNP R (bias) – 15 V Figure 14–16. D/A Output Current Booster The circuit in Figure 14–16 has been employed for decades — many resources are available that can be used to design exact component values. It boosts current because the output impedance of the op amp has been bypassed, and used as the driver for the base of the NPN and PNP power transistors. The two diodes compensate for the VBE drop in the transistors, whose bases are biased by two resistors off of the supplies. The output of the booster stage is fed back to the feedback resistor in the D/A to complete the feedback loop. The output impedance of the stage is only limited by the characteristics of the output transistors and small emitter resistors. Modern power transistors have such high frequency response that this circuit may oscillate. The RC snubber network and a small inductor in series with the load can be used to damp the oscillation — or be omitted if oscillation is not a problem. Beware of varying transistor betas, however. 14.7.2 Voltage Boosters If even more current is needed, or the output voltage swing must be more than ±15 V, the booster stage can be operated at voltages higher than the buffer amplifier potentials. A designer might be tempted to try the circuit of Figure 14–17. 14-20
Increasing Op Amp Buffer Amplifier Current and Voltage RF-EXT D/A +15 V +100 V VREF RIN D VREF/R RS RF CO CF _ + VOUT –15 V –100 V Figure 14–17. Incorrect Method of Increasing Voltage Swing of D/A Converters Any time there are higher voltage rails on the output section, there are potential hazards. The circuit above illustrates a common misapplication. The whole reason for using the booster amp is to allow the V OUT to swing to a ±100-V rail. If this circuit was operated in the unity gain mode (external R F = 0), the VOUT will only swing ±15 V, maximum. There would be no need for the ±100-V rail. That voltage rail is there to allow voltage gain. If the circuit is operated with a gain (external R larger than 0), the external R F adds to the internal R F to create the gain: Gain R FEXT R FINT R S (14–7) The problem with this is that the wattage of the resistors increases as the external voltage rail increases. The designer has control over the wattage of the external R F , but has no control whatsoever over internal R F or R S . Because these resistors are fabricated on the IC, their wattage is limited. Even if the wattage rating of the internal resistors is meticulously observed, they may have undesirable thermal coefficients if allowed to dissipate that wattage. Resistor self-heating will change the resistance according to its rated temperature coefficient (maximum). The external resistor is sure to have a different thermal coefficient from the internal resistors, causing a gain error. The designer may never have encountered the effects of resistor self-heating before, because through-hole and surfacemount devices have enough bulk to minimize the effect of self-heating. At the geometries present on IC D/As, resistor self-heating is a much more pronounced effect. It will produce a nonlinearity error in the D/A output. This effect is most pronounced in high-resolution converters, where the geometry is the smallest. The designer, therefore, must limit the current in the feedback resistor if at all possible. Figure 14–18 shows a method of achieving gain control while keeping the high current path out of the internal feedback resistor: Interfacing D/A Converters to Loads 14-21
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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
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Simultaneous Equations |m| 5.56 R
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Simultaneous Equations 4.3.4 Case 4
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Simultaneous Equations -0.10 -0.15
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Chapter 5 Feedback and Stability Th
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Block Diagram Math and Manipulation
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Block Diagram Math and Manipulation
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Bode Analysis of Feedback Circuits
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Loop Gain Plots are the Key to Unde
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The Second Order Equation and Ringi
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Chapter 6 Development of the Non Id
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Review of the Canonical Equations T
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Noninverting Op Amps 6.3 Noninverti
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Inverting Op Amps The transfer equa
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Differential Op Amps A aZ G Z G Z
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Chapter 7 Voltage-Feedback Op Amp C
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Internal Compensation Figure 7-2 sh
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Internal Compensation AVD - Large-S
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Internal Compensation - Large-Signa
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Dominant-Pole Compensation 7.4 Domi
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Dominant-Pole Compensation 100 dB D
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Lead Compensation Gain compensation
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Lead Compensation slopes down at -2
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Compensated Attenuator Applied to O
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Lead-Lag Compensation C R + _ V OUT
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Conclusions Dominant pole compensat
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Chapter 8 Current-Feedback Op Amp A
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The Noninverting CFA output impedan
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The Inverting CFA V OUT V IN Z1 Z
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Stability Analysis 8.6 Stability An
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Selection of the Feedback Resistor
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Stability and Input Capacitance Tab
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Compensation of CF and CG Z F A R
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Chapter 9 Voltage- and Current-Feed
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Bandwidth The noninverting input of
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Bandwidth The CFA is a current oper
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Impedance The CFA stability is not
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Equation Comparison Table 9-1. Tabu
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Chapter 10 Op Amp Noise Theory and
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Characterization 10.2.2 Noise Floor
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Types of Noise 10.3.1 Shot Noise Th
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Types of Noise as average dc curren
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Types of Noise Some characteristics
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Noise Colors There are an infinite
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Op Amp Noise 1000 Hz V n - Input No
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Op Amp Noise can be represented bet
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Op Amp Noise This simplifies the ga
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Putting It All Together 10.6 Puttin
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Putting It All Together When it is
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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
Page 207 and 208: impedance of the transducer. The te
Page 209 and 210: Y mX b (12-14) Two pairs of data
Page 211 and 212: Table 12-5. Offset and Gain Error B
Page 213 and 214: R G 23.7 kΩ R FB 280 kΩ R FA 200
Page 215 and 216: 12.10 Test The final circuit is rea
Page 217 and 218: Chapter 13 Wireless Communication:
Page 219 and 220: Wireless Systems ality. Image rejec
Page 221 and 222: Wireless Systems of the DAC, is usu
Page 223 and 224: Selection of ADCs/DACs The mean squ
Page 225 and 226: Selection of ADCs/DACs fication. Wi
Page 227 and 228: Anti-Aliasing Filters The op amp dy
Page 229 and 230: Communication D/A Converter Reconst
Page 231 and 232: External Vref Circuits for ADCs/DAC
Page 233 and 234: External Vref Circuits for ADCs/DAC
Page 235 and 236: High-Speed Analog Input Drive Circu
Page 237 and 238: High-Speed Analog Input Drive Circu
Page 239 and 240: Chapter 14 Interfacing D/A Converte
Page 241 and 242: Understanding the D/A Converter and
Page 243 and 244: Understanding the D/A Converter and
Page 245 and 246: D/A Converter Error Budget 14.4.1 A
Page 247 and 248: D/A Converter Error Budget 20 Ampli
Page 249 and 250: D/A Converter Errors and Parameters
Page 257: Increasing Op Amp Buffer Amplifier
Page 261 and 262: Increasing Op Amp Buffer Amplifier
Page 263 and 264: Chapter 15 Sine Wave Oscillators Ro
Page 265 and 266: Phase Shift in the Oscillator 15.3
Page 267 and 268: Active Element (Op Amp) Impact on t
Page 269 and 270: Analysis of the Oscillator Operatio
Page 271 and 272: Sine Wave Oscillator Circuits Phase
Page 273 and 274: Sine Wave Oscillator Circuits large
Page 275 and 276: Sine Wave Oscillator Circuits The i
Page 277 and 278: Sine Wave Oscillator Circuits R F 1
Page 279 and 280: Sine Wave Oscillator Circuits V OUT
Page 281 and 282: Sine Wave Oscillator Circuits resis
Page 283 and 284: Sine Wave Oscillator Circuits 15.7.
Page 285 and 286: Chapter 16 Active Filter Design Tec
Page 287 and 288: Fundamentals of Low-Pass Filters V
Page 289 and 290: Fundamentals of Low-Pass Filters A(
Page 291 and 292: Fundamentals of Low-Pass Filters 16
Page 293 and 294: Fundamentals of Low-Pass Filters 10
Page 295 and 296: Low-Pass Filter Design The multipli
Page 297 and 298: Low-Pass Filter Design C 1 R 1 R 2
Page 299 and 300: Low-Pass Filter Design V IN R 1 R 2
Page 301 and 302: Low-Pass Filter Design The general
Page 303 and 304: Low-Pass Filter Design In order to
Page 305 and 306: High-Pass Filter Design With C 1 =
Page 307 and 308: 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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