Analog Function Circuits: Fundamentals, Principles, Design and Applications

Cover
Half Title
Title Page
Copyright Page
Dedication
Table of Contents
Preface
Useful Notations
Abbreviations
Introduction
Part A: Fundamentals of Function Circuits
Chapter 1: Components of Function Circuits
1.1 Transistors
1.2 Transistor Biasing
1.3 Transistor Switches
1.4 Transistor Multiplexers
1.5 Field Effect Transistors
1.6 JFET Biasing
1.7 JFET Switches
1.8 JFET Multiplexers
1.9 MOSFET Biasing
1.10 MOSFET Switches
1.11 MOSFET Multiplexers
1.12 Analog Switch Integrated Circuits
1.13 Analog Multiplexer IC CD4053
1.14 Operational Amplifiers
Chapter 2: Linear Circuits
2.1 Buffer
2.2 Inverting Amplifier
2.3 Non-Inverting Amplifier
2.4 Control Amplifier
2.5 Inverting Adder
2.6 Non-Inverting Adder
2.7 Differential Amplifier
2.8 Instrumentation Amplifier
2.9 Voltage-to-Current Converter
2.10 Current-to-Voltage Converter
2.11 Differentiator
2.12 Integrator
2.13 Differential Integrator
2.14 Controlled Integrator
Chapter 3: Non-Linear Circuits
3.1 Voltage Comparator
3.2 Schmitt Trigger
3.3 Half-Wave Rectifier
3.4 Full Wave Rectifier
3.5 Peak Detector
3.6 Sample and Hold Circuit
3.7 Log Amplifier
3.8 Antilog Amplifier
Chapter 4: Waveform Generators
4.1 Wien Bridge Oscillator
4.2 Monostable Multivibrator
4.3 Astable Multivibrator
4.4 Sawtooth Wave Generators
4.5 Triangular Wave Generator
4.6 Voltage Controlled Function Generator
Chapter 5: Active Filters
5.1 Lowpass Filter Circuits
5.2 Highpass Filter Circuits
5.3 Bandpass Filter Circuits
5.4 Bandstop Filter Circuits
5.5 Allpass Filter Circuits
5.6 Universal Active Filter Circuits
Part B: Principles of Function Circuits
Chapter 6: Principles of Multipliers – Multiplexing
6.1 Sawtooth Wave–Based Time Division Multiplier
6.2 Triangular Wave–Based Time Division Multiplier
6.3 Time Division Multiplier with No Reference Waves
6.4 Double Dual Slope Peak Responding Multipliers with Feedback Comparator
6.5 Double Dual Slope Peak Responding Multiplier with Flip Flop
6.6 Peak Responding Multipliers with V/T Converter
Chapter 7: Principles of Multipliers – Switching
7.1 Sawtooth Wave–Based Time Division Multipliers
7.2 Triangular Wave–Based Time Division Multiplier
7.3 Time Division Multiplier with No Reference
7.4 Double Dual Slope Peak Responding Multipliers
7.5 Double Dual Slope Peak Responding Multiplier with Flip Flop
7.6 Peak Responding Multipliers with V/T Converter
Chapter 8: Principles of Analog Dividers
8.1 Time Division Divider – Multiplexing
8.2 Time Division Divider – Switching
8.3 Double Dual Slope Peak Responding Divider – Multiplexing
8.4 Double Dual Slope Peak Responding Divider – Switching
8.5 Divider Using Voltage-to-Frequency Converter – Multiplexing
8.6 Peak Responding Dividers Using Voltage-to-Frequency Converter – Switching Type
Chapter 9: Principles of Time Division Multipliers- Cum-Dividers
9.1 Sawtooth Wave–Based Multiplier-Cum-Divider – Multiplexing
9.2 Triangular Wave–Based Multiplier-Cum-Divider – Multiplexing
9.3 Time Division Multiplier-Cum-Divider with No Reference; Type I – Multiplexing
9.4 Time Division Multiplier-Cum-Divider with No Reference; Type II – Multiplexing
9.5 Sawtooth Wave–Based Multiplier-Cum-Divider – Switching
9.6 Triangular Wave–Based Time Division Multiplier-Cum-Divider – Switching
9.7 Time Division Multiplier-Cum-Divider with No Reference; Type I – Switching
9.8 Time Division Multiplier-Cum-Divider with No Reference; Type II – Switching
Chapter 10: Principles of Peak Responding Multipliers- Cum-Dividers
10.1 Double Single Slope Peak Responding Multipliers-Cum-Dividers
10.2 Double Dual Slope Peak Responding Multipliers-Cum-Dividers with Feedback Comparator
10.3 Double Dual Slope Multipliers-Cum-Dividers Using Flip Flop
10.4 Pulse Width Integrated Peak Detecting Multiplier-cum-Divider
10.5 Pulse Position Peak Responding Multiplier-Cum-Divider
10.6 Peak Responding Multiplier-Cum-Divider Using Voltage Tunable Astable Multivibrator
Part C: Design of Function Circuits
Chapter 11: Design of Analog Multipliers – Multiplexing
11.1 Triangular Wave–Based Time Division Multipliers
11.2 Time Division Multiplier with No Reference
11.3 Double Dual Slope Peak Responding Multipliers
11.4 Peak Responding Multipliers with Voltage-to-Period Converter
Chapter 12: Design of Analog Multipliers – Switching
12.1 Sawtooth Wave–Based Time Division Multipliers – Type I
12.2 Sawtooth Wave–Based Time Division Multipliers – Type II
12.3 Triangular Wave–Based Time Division Multipliers – Type I
12.4 Triangular Wave–Based Time Division Multipliers – Type II
12.5 Time Division Multipliers with No Reference – Type I
12.6 Double Dual Slope Peak Responding Multipliers
12.7 Peak Responding Multipliers with Voltage-to-Period Converter – Switching Type
12.8 Pulse Position Peak Responding Multiplier
Chapter 13: Design of Analog Dividers
13.1 Time Division Divider with No Reference – Multiplexing
13.2 Time Division Divider without Reference – Switching
13.3 Double Dual Slope Peak Responding Dividers – Multiplexing
13.4 Double Dual Slope Peak Responding Dividers – Switching
13.5 Peak Responding Dividers using Voltage-to-Frequency Converter –Multiplexing
13.6 Peak Responding Dividers using Voltage-to-Frequency Converter – Switching Type
Chapter 14: Design of Time Division Multiplier-Cum-Divider – Multiplexing
14.1 Sawtooth Wave–Based Multiplier-Cum-Divider – Type I
14.2 Sawtooth Wave–Based Multiplier-Cum-Divider – Type II
14.3 Sawtooth Wave–Based Multiplier-Cum-Divider – Type III
14.4 Triangular Wave–Based Time Division Multiplier-Cum-Divider – Type I
14.5 Triangular Wave–Based Time Division Multiplier-Cum-Divider – Type II
14.6 Triangular Wave–Based Multiplier-Cum-Divider – Type III
14.7 Time Division Multiplier-Cum-Divider with No Reference – Type I
14.8 Time Division Multiplier-Cum-Divider with No Reference – Type II
Chapter 15: Design of Time Division Multiplier-Cum-Divider – Switching
15.1 Sawtooth Wave–Based Double Switching–Averaging Time Division Multiplier-Cum-Divider
15.2 Sawtooth Wave–Based Time Division Multiply–Divide Multiplier-Cum-Divider
15.3 Sawtooth Wave–Based Time Division Divide–Multiply Multiplier-Cum-Divider
15.4 Triangular Wave–Based Time Division Multiplier-Cum-Divider
15.5 Triangular Wave–Based Divide–Multiply Time Division Multiplier-Cum-Divider
15.6 Triangular Wave–Based Multiply–Divide Time Division Multiplier-Cum-Divider
15.7 Time Division Multiplier-Cum-Divider with No Reference – Type I – Switching
15.8 Time Division Multiplier-Cum-Divider with No Reference – Type II – Switching
Chapter 16: Design of Peak Responding Multipliers-Cum-Dividers
16.1 Double Single Slope Multipliers-Cum-Dividers – Switching
16.2 Double Dual Slope Peak Responding Multipliers-Cum-Dividers Using Feedback Comparators – Multiplexing
16.3 Double Dual Slope Peak Responding Multipliers-Cum-Dividers with Flip Flop – Multiplexing
16.4 Double Dual Slope Multipliers-Cum-Dividers with Flip Flop – Switching
16.5 Pulse Width Integrated Peak Responding Multipliers-Cum-Dividers – Switching
16.6 Multipliers-Cum-Dividers Using Voltage Tunable Astable Multivibrators – Multiplexing
16.7 Pulse Position Peak Detecting Multipliers-Cum-Dividers – Switching
16.8 Pulse Position Peak Sampling Multipliers-Cum-Dividers – Switching
Part D: General on Function Circuits
Chapter 17: Conventional Function Circuits
17.1 Log-Antilog Multiplier
17.2 Multiplier Using Field Effect Transistors
17.3 Variable Transconductance Multiplier
17.4 Gilbert's Multiplier Cell
17.5 Triangle Wave Averaging Multiplier
17.6 Quarter-Squarer Multiplier
17.7 Log-Antilog Multiplier-Cum-Divider – Type I
17.8 Log-Antilog Multiplier-Cum-Divider – Type II
17.9 Multiplier-Cum-Divider Using Field Effect Transistors
17.10 Multiplier-Cum-Divider Using MOSFETs
Chapter 18: Conversion of Function Circuits
18.1 Multiplier to Squarer
18.2 Multiplier to Divider
18.3 Multiplier to Square Rooter
18.4 Divider to Multiplier
18.5 Divider to Square Rooter
18.6 Multiplier-Cum-Divider to Multiplier
18.7 Multiplier-Cum-Divider to Divider
18.8 Multiplier-Cum-Divider to Square Rooter
18.9 Multiplier-Cum-Divider to Square Root of Multiplication
18.10 Multiplier-Cum-Divider to Squaring and Dividing
18.11 Multiplier-Cum-Divider Using Two Analog Multipliers
18.12 Multiplier-Cum-Divider Using Two Analog Dividers
18.13 Multiplier-Cum-Divider Using Two Analog Dividers in Cascade
18.14 Multiplier-Cum-Divider Using a Divider and a Multiplier
Part E: Miscellaneous Function Circuits
Chapter 19: Vector Magnitude Circuits
19.1 Vector Magnitude Circuit Using Two Multipliers
19.2 Vector Magnitude Circuit Using Three Multipliers
19.3 Vector Magnitude Circuit Using Three Triangular Wave–Based Time Division Multipliers
19.4 Vector Magnitude Circuit Using Three Sawtooth Wave-Based Time Division Multipliers
19.5 Vector Magnitude Circuit Using Two Dividers
19.6 Vector Magnitude Circuit Using Multiplier-Cum-Divider
Chapter 20: Multifunction Converters
20.1 Log-Antilog Multifunction Converters
20.1.1 Log-Antilog MFC For m = 1
20.1.2 Log-Antilog MFC for m < 1
20.1.3 Log-Antilog MFC for m > 1
20.2 Multifunction Converters Using Subtractor, Adder, Log, and Antilog Amplifiers
20.3 Multifunction Converters Using Three Log and One Antilog Amplifiers
20.4 Multifunction Converter Applications
20.4.1 Sine Function Converter
20.4.2 Cosine Function Generator
20.4.3 Arctangent Function Generator
20.5 Multifunction Converter Conversions
20.6 Exponentiator
Chapter 21: Phase Sensitive Detectors
21.1 Multiplying Phase Sensitive Detectors
21.2 Switching Phase Sensitive Detectors
21.3 Sampling Phase Sensitive Detectors
21.4 Switching-Sampling Phase Sensitive Detectors
21.5 Position-Sampled Phase Sensitive Detectors
21.6 Phase Sensitive Detectors Using 4046 PLL IC
Part F: Applications of Function Circuits
Chapter 22: Applications of Analog Multipliers
22.1 Voltage-Tunable Highpass Filters
22.2 Voltage-Tunable Lowpass Filters
22.3 Voltage-Tunable Bandpass Filters
22.4 Voltage-Tunable Bandstop Filters
22.5 Voltage-Tunable Universal Active Filters
22.6 Balanced Modulators
22.7 Amplitude Modulators
22.8 Frequency Doublers
22.9 Phase Angle Detectors
22.10 Root Mean Square Detectors
22.11 Voltage-Controlled Amplifiers
22.12 Rectifiers
Chapter 23: Impedance Measurements
23.1 Basic Impedance Measurement
23.2 Inductance Measurement by Magnitude Response
23.2.1 L Measurement in Rectangular Form
23.2.2 L Measurement in Polar Form
23.3 Inductance Measurement by Phase Angle Response
23.4 Capacitance Measurement by Magnitude Response
23.4.1 Capacitance Measurement in Rectangular Form
23.4.2 Capacitance Measurement in Polar Form
23.5 Capacitance Measurement by Phase Angle Response
23.6 Capacitance Measurement by Comparison Method
23.7 Measurement of Q Factor
23.8 Measurement of Tan δ
Chapter 24: Power and Power Factor Measurements
24.1 Active Power Measurements
24.2 Reactive Power Measurements
24.3 Measurements of Apparent Power
24.4 Measurements of Power Factor
24.5 Trivector Power Measurements
24.5.1 Power Measurement in Rectangular Form
24.5.2 Power Measurement in Polar Form
24.6 Measurement of Phase Angle and Power Factor
Chapter 25: Miscellaneous Applications of Function Circuits
25.1 Automatic Gain Control Circuit
25.2 Automatic Gain Control Circuits Using Analog Dividers
25.3 Voltage-Controlled Waveform Generator
25.4 Voltage-Controlled Quadrature Oscillator
25.5 Voltage-Controlled Exponentiator
25.6 Mass Gas Flow Measurement
25.7 Phase Locked Loop
25.8 Simulation of Equations
Appendix A: Analog Function Circuits Tutorial Kit
Index