Operational Amplifiers

Chapter 1 Fundamentals 1.1 Introduction 1.2 The Ideal Operational Amplifier. Operational Feedback 1.3 More Examples of the Ideal Amplifier at Work 1.4 Integrated Circuit Operational Amplifiers ExercisesChapter 2 Understanding Operational Amplifier Performance Parameters 2.1 Amplifier Output and Input Limitations 2.2 Gain Terminology. Feedback Principles 2.3 Summary of some of the Effects of Negative Feedback 2.4 Frequency Response Characteristics 2.5 Small Signal Closed Loop Frequency Response 2.6 Closed Loop Stability Considerations 2.7 Frequency Compensation (Phase Compensation) 2.8 Transient Response Characteristics 2.9 Full Power Response 2.10 Offsets, Bias Current and Drift 2.11 Common Mode Rejection 2.12 Amplifier Impedances 2.13 Noise in Operational Amplifier Circuits ExercisesChapter 3 Amplifier Testing. Measurement of Parameters 3.1 Measurement of Bias Current, Input Difference Current, Input Offset Voltage and Their Drift Coefficients 3.2 Amplifier Noise 3.3 Measurement of Input Impedances 3.4 Maximum Common Mode Voltage 3.5 Measurement of Open Loop Voltage Gain and Output Dynamic Range 3.6 Anomalies in d.c. Open Loop Gain Values Revealed by Open Loop Transfer Curves 3.7 Input/output Transfer Curves Allow the Measurement of Amplifier d.c. Parameters 3.8 Dynamic Response Measurements 3.9 Large Signal Response MeasurementsChapter 4 Applications. Baste Scaling Circuits 4.1 Introduction 4.2 Voltage Sealers and Impedance Conversion 4.3 Voltage Summation 4.4 Differential Input Amplifier Configurations (Voltage Subtractors) 4.5 Current Scaling 4.6 Voltage to Current Conversion 4.7 A.C. Amplifiers ExercisesChapter 5 Nonlinear Circuits 5.1 Amplifiers with Defined Nonlinearity 5.2 Synthesized Nonlinear Response 5.3 Logarithmic Conversion with an Inherently Logarithmic Device 5.4 Log Amplifiers; Practical Design Considerations 5.5 Some Practical Log and Antilog Circuit Configurations 5.6 Log Antilog Circuits for Computation 5.7 A Variable Transconductance Four Quadrant Multiplier ExercisesChapter 6 Integrators and Differentiators 6.1 The Basic Integrator 6.2 Integrator Run, Set and Hold Modes 6.3 Integrator Errors 6.4 Extensions to a Basic Integrator 6.5 Integrator Reset 6.6 A.C. Integrators 6.7 Differentiators 6.8 Practical Considerations in Differentiator Design 6.9 Modifications to the Basic Differentiator 6.10 Analogue Computation 6.11 A Simple Analogue Computer ExercisesChapter 7 Switching and Positive Feedback Circuits 7.1 Comparators 7.2 Multivibrators 7.3 Sine Wave Oscillators 7.4 Waveform Generators ExercisesChapter 8 Further Measurement and Processing Applications 8.1 Transducer Amplifiers 8.2 Resistance Measurement 8.3 Capacitance Measurement 8.4 Hot Wire Anemometer with Constant Temperature Operation 8.5 Chemical Measurements 8.6 Active Filters 8.7 Phase Shifting Circuit (All Pass Filter) 8.8 Capacitance Multipliers 8.9 Averaging 8.10 Precise Diode Circuits 8.11 Sample Hold Circuits 8.12 Circuit with Switched Gain Polarity 8.13 Voltage to Frequency Conversion 8.14 Frequency to Voltage Conversion 8.15 Modulation ExercisesChapter 9 Practical Considerations 9.1 Amplifier Selection, Design Specification 9.2 Selection Processes 9.3 Attention to External Circuit Details 9.4 Avoiding Unwanted Signals 9.5 Ensure Closed Loop Stability 9.6 Offset Nulling Techniques 9.7 Importance of External Passive Components 9.8 Avoiding Fault Conditions 9.9 Modifying an Amplifier's Output Capability 9.10 Speeding up a Low Drift Amplifier 9.11 Single Power Supply Operation for Operational Amplifiers 9.12 Quad Operational Amplifiers ExercisesAppendicesAnswers to ExercisesIndex