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

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Input Common-Mode Range 18-6 sible to separate from the transducer signal. When transducers are connected to the electronics, cabling picks up noise, and some transducers like thermocouples can pick up noise from the connecting junctions. Thus, the signal is never clean as it enters the electronics. The noise generated by the op amp was defined in the previous section as V n, I nR EQ, I nRR, and ∆V/k SVR, and this noise is added to the signal. The transducer often has a very small output voltage swing, so when the transducer output voltage swing is converted to least significant bits (LSB) the noise voltage should be very small compared to an LSB. Consider a temperature transducer that has a 10-mV swing over its range. When the transducer output voltage swing is considered to be the full-scale voltage (FSV) of an ADC, the LSB is very small as is shown in Equation 18–6 for a 12-bit (N) ADC. LSB FSV 10 mV 10 mV 2N 212 4096 2.44 V (18–6) The op amp for this application must be a very low noise op amp because an op amp with a 20-nV/(Hz) 1/2 equivalent input noise voltage and a bandwidth of 4 MHz contributes 40 µV of noise. This high noise contribution is why extensive filtering and “optimally” low bandwidth is found desirable in the input stages of some electronic systems. If there is power supply noise, some of that noise passes through the op amp to its input. The power supply noise is divided by the power supply rejection ratio, but there is always a residual noise component of the power supply on the op amp input as shown in Equation 18–7 where k SVR is 60 dB. 18.4 Input Common-Mode Range VPS(INPUT) VPS 10 mV 10 V kSVR 1000 (18–7) Years ago the op amp’s input common-mode voltage range (V ICR) did not include the power supply rails. The best V ICR that was available was (V CC +|V EE|–6 V), and when the input voltage approached V ICR, distortion occurred. If the input voltage exceeded the power supply rails, the output stage might invert phase (it sometimes latched in the inverted position causing control problems) or the IC might self destruct. The vast majority of transducers were connected to ground (0 V) because it was easy to make a ground connection and because a split supply op amp has inputs referenced to ground. In a split supply application with the transducer connected to ground, latch-up or self destruction is unlikely. In special cases, transducers are connected to a power supply rail (usually V CC when power supply current sensing) or some other voltage, and in this special case, additional bias circuitry was added to split power supply designs to keep the input voltage swing within V ICR. Bias circuitry in conjunction with external components removed the effects of the power supply rail connection.
Input Common-Mode Range Many low voltage op amp input signals come from transducers connected to a power supply rail like the circuit shown in Figure 18–2. V1 Figure 18–2. Noninverting Op Amp RG V2 RF || RG RF +VCC _ + VOUT When V 1 = 0 and V 2 is the transducer input, the op amp must be capable of handling input voltages that go to 0 V. Furthermore, the transducer voltage may be ac, so it swings above and below ground, thus the transducer voltage drops below the low power supply rail. This situation requires that the op amp’s V ICR exceed the power supply voltage. Rail-to-rail input (RRI) voltage capability is a necessary requirement for a low-voltage op amp that handles transducers connected to a power supply rail. When the input voltage is connected to ground and the input voltage swing is very small, a standard op amp like the LM324 suffices. Referring to Figure 18–3 it can be seen that the PNP input transistors are biased by the emitter current source. If the positive input is connected to ground bias current still flows and the transistor stays active. If the input transistors are selected very carefully for operation with low collector-base junction reverse bias, the input voltage can go slightly below ground (–200 mV for the TLV278X) and the op amp will still operate correctly. The circuit operation is one sided though because when the input voltage approaches the positive supply rail, the emitter current source and input transistors turn off. This type of circuit does not offer rail-to-rail operation, but it does offer from rail to (V CC –1.5V) operation. Designing Low-Voltage Op Amp Circuits 18-7
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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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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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Page 328 and 329: General Considerations 17.1.3 Noise
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Page 358 and 359: Introduction 18-2 swing at V CC = 5
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Page 370 and 371: Transducer to ADC Analog Interface
Page 372 and 373: DAC to Actuator Analog Interface 18
Page 374 and 375: DAC to Actuator Analog Interface 18
Page 376 and 377: Comparison of Op Amps 18-20 When DA
Page 378 and 379: 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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