"Chapter 1 - The Op Amp's Place in the World" - HTL Wien 10

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All-Pass Filter Design 16-46 V IN f C T gr0 t gr0 1.087 kHz To complete the design, look up the filter coefficients for a seventh-order all-pass filter, specify C, and calculate the resistor values for each partial filter. Cascading the first-order all-pass with the three second-order stages results in the desired seventh-order all-pass filter. R 11 R 1 R 12 R 13 R 14 Figure 16–45. Seventh-Order All-Pass Filter R 11 C 1 C 2 C 2 R 22 C 3 C 3 R 23 C 4 C 4 R 24 R 32 R 2 R 33 R 3 R 34 R 4 R 2 R 3 R 4 V OUT
16.8 Practical Design Hints Active Filter Design Techniques Practical Design Hints This section introduces dc-biasing techniques for filter designs in single-supply applications, which are usually not required when operating with dual supplies. It also provides recommendations on selecting the type and value range of capacitors and resistors as well as the decision criteria for choosing the correct op amp. 16.8.1 Filter Circuit Biasing The filter diagrams in this chapter are drawn for dual supply applications. The op amp operates from a positive and a negative supply, while the input and the output voltage are referenced to ground (Figure 16–46). V IN Figure 16–46. Dual-Supply Filter Circuit C 1 R 1 R 2 +V CC – V CC For the single supply circuit in Figure 16–47, the lowest supply voltage is ground. For a symmetrical output signal, the potential of the noninverting input is level-shifted to midrail. C IN RB R1 Figure 16–47. Single-Supply Filter Circuit V IN R B VMID R 2 The coupling capacitor, C IN in Figure 16–47, ac-couples the filter, blocking any unknown dc level in the signal source. The voltage divider, consisting of the two equal-bias resistors R B, divides the supply voltage to V MID and applies it to the inverting op amp input. For simple filter input structures, passive RC networks often provide a low-cost biasing solution. In the case of more complex input structures, such as the input of a second-order +V CC V OUT V OUT 16-47
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Operational Amplifier Chapter 1: Th
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1-2 problem. It seems that circuits
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1-4 you are looking in the wrong pl
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Laws of Physics 2-2 V IR (2-1) In
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Current Divider Rule 2-4 put voltag
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Thevenin’s Theorem 2-6 V theorem
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Superposition 2.6 Superposition 2-8
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Transistor Amplifier 2-10 I C I B
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Transistor Amplifier 2-12 approxima
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Ideal Op Amp Assumptions 3-2 a hard
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The Inverting Op Amp 3-4 in a curre
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The Differential Amplifier 3.5 The
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Complex Feedback Networks 3-8 Break
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Capacitors Figure 3-10. Low-Pass Fi
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3-12
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Single Supply versus Dual Supply 4-
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Circuit Analysis 4-4 VREF VIN Figur
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Circuit Analysis 4-6 Four op amps w
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Simultaneous Equations 4.3 Simultan
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Simultaneous Equations 4-10 VOUT V
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Simultaneous Equations 4-12 VIN = 0
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Simultaneous Equations 4-14 m R F
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Simultaneous Equations 4.3.3 Case 3
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Simultaneous Equations 4-18 - Input
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Simultaneous Equations 4-20 |b| V
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Summary 4.4 Summary 4-22 Single-sup
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Block Diagram Math and Manipulation
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Block Diagram Math and Manipulation
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Feedback Equation and Stability 5.3
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Bode Analysis of Feedback Circuits
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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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Loop Gain Plots are the Key to Unde
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References 5-16 M tangent 1 (2) (
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Review of the Canonical Equations 6
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Review of the Canonical Equations 6
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Inverting Op Amps 6-6 comparison al
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Differential Op Amps 6.5 Differenti
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6-10
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Internal Compensation 7-2 around in
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Internal Compensation 7-4 Damping R
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Internal Compensation AVD - Large-S
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External Compensation, Stability, a
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Dominant-Pole Compensation 7-10 VTH
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Gain Compensation 7-12 VOUT VIN a
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Lead Compensation 7-14 transfer fun
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Compensated Attenuator Applied to O
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Lead-Lag Compensation 7-18 FHASE (A
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Comparison of Compensation Schemes
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7-22
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Development of the Stability Equati
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The Noninverting CFA Figure 8-4. No
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The Inverting CFA 8-6 The current e
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Stability Analysis 8-8 The plot in
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Selection of the Feedback Resistor
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Stability and Feedback Capacitance
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Summary 8.11 Summary 8-14 A Z1 R
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Precision 9.2 Precision 9-2 The lon
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Bandwidth 9-4 A aR G R F R G (9-2
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Stability 9.4 Stability 9-6 Substit
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Equation Comparison 9-8 R G = 100
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9-10
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Characterization 10-2 Noise Signal
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Types of Noise 10.2.5 Noise Units 1
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Types of Noise 10-6 Shot noise is
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Types of Noise 10-8 Ith 4kTB R Wh
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Noise Colors Figure 10-4. Avalanche
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Op Amp Noise 10.4.3 Red/Brown Noise
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Op Amp Noise 10-14 E n Square it.
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Op Amp Noise 10.5.4 Inverting Op Am
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Op Amp Noise 10.5.6 Differential Op
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Putting It All Together 10-20 Vn Vn
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Putting It All Together 10-22 volta
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10-24
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Operational Amplifier Parameter Glo
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Additional Parameter Information 11
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12-2 The ADC selection is based on
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12-4 (A) 4 V 3 V ADC 0 V Sensor Out
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12.2 Transducer Types 12-6 This is
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12-8 some value, and R X is switche
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12-10 Resolvers and synchros are po
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12-12 6) Scan the transducer and AD
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12-14 the worst case excursions of
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Table 12-3. Op Amp Selection 12-16
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12-18 this yields m = 16.16. The re
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12-20 0.97R 1 VREF(MIN) VREF 50 m
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12-22 ply contribution is reduced b
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12-24
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Wireless Systems 13-2 Signal @ - 10
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Wireless Systems 13-4 900 MHz Figur
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Selection of ADCs/DACs 13.3 Selecti
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Selection of ADCs/DACs 13-8 Therefo
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Factors Influencing the Choice of O
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Anti-Aliasing Filters 13-12 anti-al
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Communication D/A Converter Reconst
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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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References 13.9 References 13-22 [1
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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 14-6 rat
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D/A Converter Error Budget 14-8 The
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D/A Converter Errors and Parameters
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Compensating For DAC Capacitance 14
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Increasing Op Amp Buffer Amplifier
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Increasing Op Amp Buffer Amplifier
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14-24
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Requirements for Oscillation 15-2 u
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Gain in the Oscillator 15-4 The fre
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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 15-10
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Page 258 and 259: Sine Wave Oscillator Circuits 15-18
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Page 262 and 263: References 15.8 References 15-22 [1
Page 264 and 265: Fundamentals of Low-Pass Filters 16
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Page 284 and 285: High-Pass Filter Design 16-22 |A|
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Page 298 and 299: Band-Rejection Filter Design 16-36
Page 304 and 305: All-Pass Filter Design 16-42 2 i
Page 306 and 307: All-Pass Filter Design 16.7.1 First
Page 310 and 311: Practical Design Hints 16-48 low-pa
Page 312 and 313: Practical Design Hints V IN 16-50 C
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Page 318 and 319: Filter Coefficient Tables Table 16-
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Page 328 and 329: General Considerations 17.1.3 Noise
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Introduction 18-2 swing at V CC = 5
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Dynamic Range 18-4 VIN VnR Figure 1
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Input Common-Mode Range 18-6 sible
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Input Common-Mode Range 18-8 VCC GN
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Input Common-Mode Range 18-10 V µ
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Shutdown and Low Current Drain 18-1
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Transducer to ADC Analog Interface
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DAC to Actuator Analog Interface 18
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DAC to Actuator Analog Interface 18
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Comparison of Op Amps 18-20 When DA
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Summary 18.11 Summary 18-22 Always
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18-24
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"Chapter 1 - The Op Amp's Place in the World" - HTL Wien 10

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