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

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Internal Compensation 7-2 around in the ’60s, so we used them. Internally compensated op amps were introduced in the late ’60s in an attempt to make op amps easy for everyone to use. Unfortunately, internally compensated op amps sacrifice a lot of bandwidth and still oscillate under some conditions, so an understanding of compensation is required to apply op amps. Internal compensation provides a worst-case trade-off between stability and performance. Uncompensated op amps require more attention, but they can do more work. Both are covered here. Compensation is a process of applying a judicious patch in the form of an RC network to make up for a less than perfect op amp or circuit. There are many different problems that can introduce instability, thus there are many different compensation schemes. 7.2 Internal Compensation Op amps are internally compensated to save external components and to enable their use by less knowledgeable people. It takes some measure of analog knowledge to compensate an analog circuit. Internally compensated op amps normally are stable when they are used in accordance with the applications instructions. Internally compensated op amps are not unconditionally stable. They are multiple pole systems, but they are internally compensated such that they appear as a single pole system over much of the frequency range. Internal compensation severely decreases the possible closed-loop bandwidth of the op amp. Internal compensation is accomplished in several ways, but the most common method is to connect a capacitor across the collector-base junction of a voltage gain transistor (see Figure 7–1). The Miller effect multiplies the capacitor value by an amount approximately equal to the stage gain, thus the Miller effect uses small value capacitors for compensation. VIN Figure 7–1. Miller Effect Compensation RB C VCC RC
AAVD VD – Large-Signal Differential Voltage Amplification – V/mV Á Á 10 k 1 k 100 10 1 Voltage-Feedback Op Amp Compensation Internal Compensation Figure 7–2 shows the gain/phase diagram for an older op amp (TL03X). When the gain crosses the 0-dB axis (gain equal to one) the phase shift is approximately 108°, thus the op amp must be modeled as a second-order system because the phase shift is more than 90°. LARGE-SIGNAL DIFFERENTIAL VOLTAGE AMPLIFICATION AND PHASE SHIFT vs FREQUENCY 100 k 0° 0.1 10 AVD Phase Shift 30° 60° 90° 120° 150° 100 1 k 10 k 100 k 180° 1 M 10 M f – Frequency – Hz VCC ± = 15 V RL = 10 kΩ CL = 25 pF TA = 25°C Phase Shift VO – Output Voltage – mV VOLTAGE-FOLLOWER SMALL-SIGNAL PULSE RESPONSE 16 12 8 4 0 –4 –8 –12 ÁÁ ÁÁ Figure 7–2. TL03X Frequency and Time Response Plots –16 0 0.2 0.6 1.0 t – Time – µs VCC ± = 15 V RL = 10 kΩ CL = 100 pF TA = 25°C This yields a phase margin of φ = 180° – 108° = 72°, thus the circuit should be very stable. Referring to Figure 7–3, the damping ratio is one and the expected overshoot is zero. Figure 7–2 shows approximately 10% overshoot, which is unexpected, but inspecting Figure 7–2 further reveals that the loading capacitance for the two plots is different. The pulse response is loaded with 100 pF rather than 25 pF shown for the gain/phase plot, and this extra loading capacitance accounts for the loss of phase margin. 1.4 7-3
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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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Page 32 and 33: Single Supply versus Dual Supply 4-
Page 34 and 35: Circuit Analysis 4-4 VREF VIN Figur
Page 36 and 37: Circuit Analysis 4-6 Four op amps w
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Page 40 and 41: Simultaneous Equations 4-10 VOUT V
Page 42 and 43: Simultaneous Equations 4-12 VIN = 0
Page 44 and 45: Simultaneous Equations 4-14 m R F
Page 46 and 47: Simultaneous Equations 4.3.3 Case 3
Page 48 and 49: Simultaneous Equations 4-18 - Input
Page 50 and 51: Simultaneous Equations 4-20 |b| V
Page 52 and 53: Summary 4.4 Summary 4-22 Single-sup
Page 54 and 55: Block Diagram Math and Manipulation
Page 56 and 57: Block Diagram Math and Manipulation
Page 58 and 59: Feedback Equation and Stability 5.3
Page 60 and 61: Bode Analysis of Feedback Circuits
Page 62 and 63: Bode Analysis of Feedback Circuits
Page 64 and 65: Loop Gain Plots are the Key to Unde
Page 66 and 67: Loop Gain Plots are the Key to Unde
Page 68 and 69: References 5-16 M tangent 1 (2) (
Page 70 and 71: Review of the Canonical Equations 6
Page 72 and 73: Review of the Canonical Equations 6
Page 74 and 75: Inverting Op Amps 6-6 comparison al
Page 76 and 77: Differential Op Amps 6.5 Differenti
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Page 82 and 83: Internal Compensation 7-4 Damping R
Page 84 and 85: Internal Compensation AVD - Large-S
Page 86 and 87: External Compensation, Stability, a
Page 88 and 89: Dominant-Pole Compensation 7-10 VTH
Page 90 and 91: Gain Compensation 7-12 VOUT VIN a
Page 92 and 93: Lead Compensation 7-14 transfer fun
Page 94 and 95: Compensated Attenuator Applied to O
Page 96 and 97: Lead-Lag Compensation 7-18 FHASE (A
Page 98 and 99: Comparison of Compensation Schemes
Page 100 and 101: 7-22
Page 102 and 103: Development of the Stability Equati
Page 104 and 105: The Noninverting CFA Figure 8-4. No
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Page 108 and 109: Stability Analysis 8-8 The plot in
Page 110 and 111: Selection of the Feedback Resistor
Page 112 and 113: Stability and Feedback Capacitance
Page 114 and 115: Summary 8.11 Summary 8-14 A Z1 R
Page 116 and 117: Precision 9.2 Precision 9-2 The lon
Page 118 and 119: Bandwidth 9-4 A aR G R F R G (9-2
Page 120 and 121: Stability 9.4 Stability 9-6 Substit
Page 122 and 123: Equation Comparison 9-8 R G = 100
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Page 126 and 127: Characterization 10-2 Noise Signal
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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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References 15.8 References 15-22 [1
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Fundamentals of Low-Pass Filters 16
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Low-Pass Filter Design 16-12 1st or
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Low-Pass Filter Design Example 16-1
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Low-Pass Filter Design 16-16 In ord
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Low-Pass Filter Design 16.3.2.2 Mul
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Low-Pass Filter Design Second Filte
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High-Pass Filter Design 16-22 |A|
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High-Pass Filter Design 16-24 To di
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High-Pass Filter Design 16-26 Throu
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Band-Pass Filter Design 16-28 |A| [
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Band-Pass Filter Design 16-30 The g
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Band-Pass Filter Design 16-32 out a
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Band-Pass Filter Design 16-34 After
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Band-Rejection Filter Design 16-36
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All-Pass Filter Design 16-42 2 i
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All-Pass Filter Design 16.7.1 First
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All-Pass Filter Design 16-46 V IN f
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Practical Design Hints 16-48 low-pa
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Practical Design Hints V IN 16-50 C
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Practical Design Hints 16-52 If thi
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Practical Design Hints 16-54 f T 1
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Filter Coefficient Tables Table 16-
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16-64
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General Considerations 17.1.3 Noise
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PCB Mechanical Construction 17-4 Te
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PCB Mechanical Construction 17.2.2.
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Grounding 17-8 DIGITAL + DIGITAL -
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Grounding 17-10 CONNECTOR POWER SUP
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The Frequency Characteristics of Pa
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Decoupling 17-20 For example, a 0.4
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Decoupling 17-22 EQUIVALENT SERIES
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Packages 17.7 Packages 17-24 N1 IN-
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Packages 17-26 IN1 + OUT1 IN2 IN3 O
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Summary 17-28 HALF SUPPLY GOOD _ +
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17-30
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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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"Chapter 1 - The Op Amp's Place in the World" - HTL Wien 10

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