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

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Broadcasting, from PCB traces, 17-9 Bridge, wheatstone, 12-8 Broadband noise, 11-18 Brown noise, 10-12 Bubba oscillator, 15-17 to 15-19 circuit, 15-17 Burst noise, 10-9 to 10-11 Butterworth band-pass filter, gain response graph, 16-36 Butterworth low-pass filter, 16-6 amplitude response graph, 16-6 circuit with unity gain, 16-21 graph, 16-51 Tschebyscheff-type characteristic, 16-51 C Cable amplifier, 3-9 Canonical equations, 6-2 to 6-5 Canonical feedback, 15-2 Capacitance effect on inverting op amp, 17-18 trace to plane, 17-17 Capacitively-loaded loop-gain calculation circuit, 7-9 op amp circuit, 7-9 Capacitor, 3-9 to 3-11 high-frequency circuit, 17-12 self resonance, 17-22 Cascading filter stages, 16-12 CDMA cellular base station, transmitter block diagram, 13-5 Cellular base station receiver, block diagram, 13-2 CFA. See current feedback amplifier Characterization, transducer, 12-13 to 12-16 Circuit active full-wave rectifier and filter, 12-10 active Wien-Robinson filter circuit, 16-39 ADC singled-ended input drive, 13-20 adder, 3-5 AIA, 12-17 analog interface, 12-21 analysis done the hard way, 2-7 automatic gain control, 15-13 band reject filter, 5-9 Bessel high-pass filter, 16-27 bubba oscillator, 15-17 Butterworth low-pass filter circuit with unity gain, 16-21 canonical feedback, 5-6 capacitively-loaded op amp, 7-9 compensated attenuator, 7-17 complex feedback networks, 3-7 control canonical feedback, 5-6 current divider rule, 2-4 current feedback amplifier, 8-2 DAC current booster, 14-20 DAC current sink to actuator interface, 18-19 DAC current source to actuator interface, 18-17 DAC deglitch, 14-17 DAC voltage booster, 14-21, 14-22 differential amplifier, 3-6, 3-7 differential op amp, 6-8 dual-supply filter, 16-47 electronic canonical feedback, 5-6 feedback, 5-6 feedback loop broken, 6-7 first-order all-pass filter, 16-44 first-order high-pass filter, 16-23 first-order inverting high-pass filter, 16-23 first-order inverting low-pass filter, 16-13 first-order low-pass filter, 16-12 first-order noninverting low-pass filter, 16-14 first-order passive RC low pass filter, 16-2 fourth-order passive RC low pass filter, 16-3 high-frequency capacitor, 17-12 high-frequency inductor, 17-13 high-pass filter, 3-10 high-performance resistor, 17-11 high-speed analog input drive, 13-18 to 13-22 ideal current feedback amp, 9-3 ideal op amp, 3-2 input current, 11-10 input for an RRI op amp, 18-8 input for nonRRI op amp, 18-8 input offset voltage, 11-9 input offset voltage adjustment, 11-9 input parasitic elements, 11-13 inverting, 6-6, 6-7 inverting current feedback amp, 8-5 inverting op amp, 3-4 Kirchoff’s current law, 2-3 Kirchoff’s voltage law, 2-2 lead-lag compensation, 7-19 logic gate output, 17-21 long-tailed pair, 9-2 loop gain calculation, 7-9 Index-2
low pass filter, 16-1 low-pass filter, 3-10, 5-8 low-pass filter circuit with unity gain, 16-19 maximum output voltage swing, 11-12 MFB band-pass filter, 16-31 MFB high-pass filter biasing, 16-50 MFB low-pass filter biasing, 16-49 Miller effect compensation, 7-2 noninverting current feedback amp, 8-4 noninverting op amp, 3-3, 18-7 nonlinear feedback, 15-12 Ohm’s law, 2-2 op amp design, 12-16 to 12-23 op amp terminal model, 17-5 op amp with negative feedback, 15-8 op amp with positive feedback, 15-8 original amplifier, 2-5 passive twin-T filter, 16-37 passive Wien-Robinson bridge circuit, 16-39 phase shift oscillator, 15-14 phase shift oscillator, buffered, 15-16 photodiode amplifier, 12-8 phototransistor amplifier, 12-9 photovoltaic cell amplifier, 12-9 quadrature oscillator, 15-19 reference bias, 12-13 RRO output stage, 18-11 Sallen-Key band-pass filter, 16-30 Sallen-Key high-pass filter, 16-24 Sallen-Key high-pass filter biasing, 16-50 Sallen-Key low-pass filter, 16-15 Sallen-Key low-pass filter biasing, 16-48 Sallen-Key low-pass filter circuit, 16-20 saturated transistor, 2-9 second-order all-pass filter, 16-44 second-order low-pass filter, 16-17 second-order MFB high-pass filter, 16-25 second-order MFB low-pass filter, 16-18 second-order Tschebyscheff low-pass filter, 16-16 seventh-order all-pass filter, 16-46 simplified op amp, 11-17 simultaneous equation , 4-12, 4-15, 4-17, 4-20 single supply, 4-1, 4-3 common-mode voltage, 4-2 reference voltage input, 4-2 single supply inverting op amp, 4-4, 4-5 single supply noninverting, 4-7 single-ended to diff output, 13-18 single-pole reconstruction filter, 13-15 single-supply DAC, 14-23 single-supply filter, 16-47 slew rate, 11-16 split-supply op amp, 10-19 stability analysis, 8-2, 8-3 stray capacitance on inverting input, 7-16 superposition example, 2-8 T network, 3-8 Thevenim equivalent of the base circuit, 2-11 Thevenim’s equivalent, 2-5, 2-6 TLC2201, 10-21, 10-23 traducer bias, 12-13 transducer to ADC interface, 18-15, 18-16 transistor, 2-10 video amplifier, 3-9 voltage divider rule, 2-3 voltage feedback amp, 9-2 voltage reference filter, 13-16 Wein bridge oscillator, 15-12 Wein bridge oscillator with AGC, 15-13 wheatstone bridge, 12-8 Wien bridge oscillator, 15-9, 15-11 Wien-Robinson bridge circuit, 16-39 Wien-Robinson circuit, 16-39 Circuit board layout, 17-1 to 17-30 component of op amp design, 17-1 noise sources, 17-2 prototype, 17-1 to 17-3 Circuit Theory, op amps, 2-1 to 2-13 Closed loop response, diff amp graph, 13-19 Colors, noise, 10-10 to 10-13 Common-mode range, op amp, 18-6 to 18-10 Common-mode rejection ratio, 11-15 Compensated attenuator, 7-16 to 7-19 circuit, 7-17 Compensation comparison of schemes, 7-20 to 7-22 DAC, 14-18 to 14-20 dominant pole graph, 7-11 dominant-pole, 7-9 to 7-13 external, 7-8 feedback capacitance, 8-13 to 8-15 gain, 7-12 to 7-14 gain capacitance, 8-13 graph, 7-12, 7-13 internal op amp, 7-2 to 7-9 inverting op amp, 7-15 lead, 7-13 to 7-17 lead-lag, 7-18 to 7-21 Miller effect, 7-2 to 7-4 Index-3
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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
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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
Page 401 and 402: Summary mon-mode range of the op am
Page 403 and 404: Appendix A Single-Supply Circuit Co
Page 405 and 406: Introduction + 5 V R G R F +V CC _
Page 407 and 408: Amplifiers A.3 Amplifiers Many type
Page 409 and 410: Amplifiers A.3.3 Inverting Op Amp w
Page 411 and 412: Amplifiers A.3.5 Noninverting Op Am
Page 413 and 414: Amplifiers A.3.7 Noninverting Op Am
Page 415 and 416: Amplifiers A.3.9 Differential Ampli
Page 417 and 418: Amplifiers A.3.11 High Input Impeda
Page 419 and 420: Amplifiers A.3.13 High-Precision Di
Page 421 and 422: Amplifiers A.3.15 Variable Gain Dif
Page 423 and 424: Amplifiers A.3.17 Buffer The buffer
Page 425 and 426: Amplifiers A.3.19 Noninverting AC A
Page 427 and 428: Computing Circuits A.4.2 Noninverti
Page 429 and 430: Computing Circuits A.4.4 Inverting
Page 435 and 436: Computing Circuits A.4.10 Noninvert
Page 439 and 440: Oscillators A.5 Oscillators This se
Page 441 and 442: Oscillators A.5.3 Wien Bridge Oscil
Page 443 and 444: Oscillators A.5.5 Classical Phase S
Page 445 and 446: Oscillators A.5.7 Bubba Oscillator
Page 447 and 448: Appendix BA Single-Supply Op Amp Se
Page 449 and 450: Table B-1. Single-Supply Operationa
Page 451: A AC loads, DAC, 14-2 AC parameters
Page 455 and 456: esistor ladder, 14-2 to 14-4 resist
Page 457 and 458: phase shift for TL07x, 7-5 phase sh
Page 459 and 460: N Noise, 10-8 to 10-10 avalanche, 1
Page 461 and 462: packages, 17-24 to 17-27 parallel s
Page 463 and 464: Theorem Norton’s, 2-5 Superpositi
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