This textbook provides a compact but comprehensive treatment that guides students through the analysis of circuits, using Proteus®. The book focuses on solving problems using updated market-standard software, corresponding to all key concepts covered in the classroom. The author uses his extensive classroom experience to guide students toward a deeper understanding of key concepts while they gain facility with the software they will need to master for later studies and practical use in their engineering careers. The book includes detailed exercises and examples that provide better grasping to students. This book will be ideal as a hands-on source for courses in computer-aided circuit simulation, circuits, electronics, digital logic, and power electronics. Though written primarily for undergraduate and graduate students, the text will also be useful to Ph.D. scholars and practitioners in engineering who are working on Proteus.
Author(s): Farzin Asadi
Series: Energy Systems in Electrical Engineering
Publisher: Springer
Year: 2022
Language: English
Pages: 671
City: Singapore
Preface
Contents
About the Author
1 Simulation of Electric Circuits with Proteus®
Abstract
1.1 Introduction
1.2 Example 1: Simple Resistive Voltage Divider
1.3 Example 2: Project Documentation and Reporting
1.4 Example 3: Addition of Text to Schematic
1.5 Example 4: Defining Variables
1.6 Example 5: Removing the Unused Components from the Component List
1.7 Example 6: Vsource Block
1.8 Example 7: Csource Block
1.9 Example 8: Vsine Block
1.10 Example 9: Exporting the Drawn Schematic as a Graphical File
1.11 Example 10: Measurement with Probes (I)
1.12 Example 11: Measurement with Probes (II)
1.13 Example 12: Measurement with Probes (III)
1.14 Example 13: Junction Dot Mode
1.15 Example 14: Excluding a Component from Simulation
1.16 Example 15: Potentiometer Block
1.17 Example 16: Measurement with AC Voltmeter/Ammeter (I)
1.18 Example 17: Measurement with AC Voltmeter/Ammeter (II)
1.19 Example 18: Wattmeter Block (I)
1.20 Example 19: Wattmeter Block (II)
1.21 Example 20: Measurement of Power Factor
1.22 Example 21: Power Factor Correction
1.23 Example 22: Measurement of Phase Difference
1.24 Example 23: Giving a Name to Oscilloscope Blocks
1.25 Example 24: Isine Block
1.26 Example 25: Grounded Current Sources
1.27 Example 26: Thevenin Equivalent Circuit
1.28 Example 27: Making Connections Without Using the Wire (I)
1.29 Example 28: Making Connections Without Using the Wire (II)
1.30 Example 29: Current Controlled Voltage Source Block
1.31 Example 30: Current Sensor
1.32 Example 31: Voltage Controlled Current Source Block
1.33 Example 32: Three-Phase Voltage Source Block
1.34 Example 33: Voltage Difference Measurement (I)
1.35 Example 34: Voltage Difference Measurement (II)
1.36 Example 35: Transient Analysis (I)
1.37 Example 36: Transient Analysis (II)
1.38 Example 37: Transient Analysis (III)
1.39 Example 38: Transient Analysis (IV)
1.40 Example 39: Transient Analysis (V)
1.41 Example 40: Increasing the Accuracy of Transient Analysis Graph
1.42 Example 41: Copying the Waveform Graph into the Clipboard Memory
1.43 Example 42: Exporting the Waveforms into MATLAB®
1.44 Example 43: Multiplier Block
1.45 Example 44: Gain Block
1.46 Example 45: Coupled Inductors (I)
1.47 Example 46: Coupled Inductors (II)
1.48 Example 47: Single-Phase Transformer
1.49 Example 48: Single-Phase Transformer with Two Outputs
1.50 Example 49: Center Tap Transformer
1.51 Example 50: Three-Phase Transformer
1.52 Example 51: Impulse Response of a RLC Circuit (I)
1.53 Example 52: Impulse Response of an RLC Circuit (II)
1.54 Example 53: Step Response of a RC Circuit
1.55 Example 54: Pulse Response of a RC Circuit
1.56 Example 55: Frequency Response of Electric Circuits (I)
1.57 Example 56: Frequency Response of Electric Circuits (II)
1.58 Example 57: Input Impedance of Electric Circuits (I)
1.59 Example 58: Input Impedance of Electric Circuits (II)
1.60 Example 59: Input Impedance of Electric Circuits (III)
1.61 Example 60: AC Sweep Analysis
1.62 Example 61: Samples Simulations
1.63 Exercises
References for Further Study
2 Simulation of Electronic Circuits with Proteus®
Abstract
2.1 Introduction
2.2 Example 1: DC Sweep Analysis
2.3 Example 2: Diode IV Characteristic
2.4 Example 3: DC Transfer Curve Analysis
2.5 Example 4: Small Signal Resistance of Diode
2.6 Example 5: Doing the Simulation at a Specific Temperature
2.7 Example 6: LED and Push Button Blocks
2.8 Example 7: Different Kinds of Mechanical Switches
2.9 Example 8: Turning on and off a Lamp
2.10 Example 9: Turning on and off a Lamp from Two Different Points
2.11 Example 10: Measurement of Output Voltage Ripple for Half Wave Diode Rectifier
2.12 Example 11: Input Current of Half Wave Rectifier
2.13 Example 12: Full Wave Rectifier
2.14 Example 13: Measurement of Average Value of Output Voltage for Full Wave Rectifier
2.15 Example 14: Current Passed from Rectifier Diodes
2.16 Example 15: Bridge Block
2.17 Example 16: Fourier Analysis of Output Voltage of Full Wave Rectifier
2.18 Example 17: Harmonic Content of a Triangular Waveform
2.19 Example 18: Voltage Regulator (I)
2.20 Example 19: Voltage Regulator (II)
2.21 Example 20: Voltage Regulator (III)
2.22 Example 21: Common Emitter Amplifier
2.23 Example 22: Signal Generator Block
2.24 Example 23: Input Impedance of Common Emitter Amplifier
2.25 Example 24: Frequency Response of Input Impedance of Common Emitter Amplifier
2.26 Example 25: Output Impedance of Common Emitter Amplifier
2.27 Example 26: Frequency Response of Output Impedance of Common Emitter Amplifier
2.28 Example 27: Frequency Response of Amplifier
2.29 Example 28: Modeling Custom Semiconductor Devices
2.30 Example 29: Bill of Material
2.31 Example 30: Common Mode Rejection Ratio (CMRR) of Difference Amplifier
2.32 Example 31: CMRR of Differential Pair
2.33 Example 32: Measurement of Differential Mode Input Impedance of Differential Pair
2.34 Example 33: Astable Oscillator with 555
2.35 Example 34: Colpitts Oscillator
2.36 Example 35: Total Harmonic Distortion (THD) of Colpitts Oscillator
2.37 Example 36: Wien Bridge Oscillator
2.38 Example 37: Optocoupler Block
2.39 Example 38: Relay Block
2.40 Example 39: Simulation of Control Systems
2.41 Exercises
References for Further Study
3 Simulation of Digital Circuits with Proteus®
Abstract
3.1 Introduction
3.2 Example 1: Full Adder Circuit
3.3 Example 2: Logic Probe Block
3.4 Example 3: Decade Counter
3.5 Example 4: Dclock Block
3.6 Example 5: Frequency Divider Circuit
3.7 Example 6: Frequency Meter Block
3.8 Example 7: Two-Bit Binary Counter
3.9 Example 8: Generating of Desired Digital Pulses
3.10 Example 9: Digital Graph
3.11 Example 10: Boolean Block
3.12 Example 11: Bus
3.13 Example 12: Simulation of Circuits Contains a Microcontroller
3.14 Exercises
References for Further Study
4 Simulation of Power Electronics Circuits with Proteus®
Abstract
4.1 Introduction
4.2 Example 1: Buck Converter Circuit
4.3 Example 2: Operating Mode of Converter
4.4 Example 3: Efficiency of the Converter
4.5 Example 4: Dimmer Circuit
4.6 Example 5: Single-Phase Half Wave Controlled Rectifier
4.7 Example 6: Single-Phase Full Wave Controlled Rectifier
4.8 Example 7: Three-Phase Controlled Rectifier (I)
4.9 Example 8: Three-Phase Controlled Rectifier (II)
4.10 Example 9: Three-Phase Controlled Rectifier (III)
4.11 Example 10: Three-Phase Controlled Rectifier (IV)
4.12 Example 11: Harmonic Content of Output Voltage of a Rectifier
4.13 Example 12: Single-Phase Inverter
4.14 Example 13: Three-Phase Inverter
4.15 Exercises
References for Further Study
Index
