Simulation of Electrical Systems Theory and Practice 1st edition by Ashok Kumar, Indragandhi, Uma Maheswari – Ebook PDF Instant Download/Delivery: 0128194170, 9780128194171
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Product details:
ISBN 10: 0128194170
ISBN 13: 9780128194171
Author: Ashok Kumar, Indragandhi, Uma Maheswari
Simulation of Software Tools for Electrical Systems: Theory and Practice offers engineers and students what they need to update their understanding of software tools for electric systems, along with guidance on a variety of tools on which to model electrical systems—from device level to system level. The book uses MATLAB, PSIM, Pspice and PSCAD to discuss how to build simulation models of electrical systems that assist in the practice or implementation of simulation software tools in switches, circuits, controllers, instruments and automation system design.
In addition, the book covers power electronic switches and FACTS controller device simulation model building with the use of Labview and PLC for industrial automation, process control, monitoring and measurement in electrical systems and hybrid optimization software HOMER is presented for researchers in renewable energy systems.
- Includes interactive content for numerical computation, visualization and programming for learning the software tools related to electrical sciences
- Identifies complex and difficult topics illustrated by useable examples
- Analyzes the simulation of electrical systems, hydraulic, and pneumatic systems using different software, including MATLAB, LABVIEW, MULTISIM, AUTOSIM and PSCAD
Simulation of Electrical Systems Theory and Practice 1st Table of contents:
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MATLAB®/Simulink 1.1 Introduction
1.1.1 Basics of MATLAB®
1.1.1.1 Design and Simulation of Power Converters-
Single-phase Half-Controlled Converter
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Single-phase Fully Controlled Rectifier
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Three-Phase Converters
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Buck Converter
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Boost Converter
1.1.1.2 Simulation of Different Transformerless Inverters -
H-Bridge with Unipolar Modulation
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H-Bridge with Bipolar Modulation
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H-Bridge with DC Bypass (H5)
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H-Bridge with AC Bypass: Highly Efficient and Reliable Inverter Concept
1.1.1.3 H6 Topology
1.1.1.4 oH5 Topology -
Introduction
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Concept
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Types of Multilevel Inverters
1.1.1.5 Simulation Circuit and Results
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PSIM Simulation Practices 2.1 Introduction to PSIM
2.1.1 Introduction
2.1.2 Circuit Structure
2.1.3 Software/Hardware Requirements
2.1.4 Installing the Program
2.1.5 Simulating a Circuit-
Running the Simulation
2.1.6 Simulation Control -
PSIM Tab
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SPICE Tab
2.1.7 Component Parameter Specification and Format
2.2 Spice Libraries
2.2.1 Creating a Secondary Image
2.2.2 Adding a New Subcircuit Element into the Library
2.2.3 Adding a New DLL Element into the Library -
Creating the DLL
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Adding the New Element to the PSIM Library
2.2.4 Creating a Symbol Library
2.3 Rectifier PSIM Model
2.3.1 Rectifier Circuit Structure -
AC Supply Section
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Diode Bridge Section
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Filter Section
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Load and Adding Meters
2.3.2 Simulation Procedure -
Simulation Control Parameters
2.3.3 Simulation Waveforms -
Capacitor Current
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Inductor Current
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Load Current
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Source Current
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Source Voltage and Load Voltage
2.3.4 Measuring Power Factor
2.4 IGBT Thermal Model
2.4.1 IGBT Device in Database -
General Information
2.4.2 IGBT Loss Calculation -
Attributes
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Conduction Losses
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Switching Losses
2.4.3 Curve Fitting with Manufacturer Datasheet (SEMiX151GD066HDs)
2.5 Renewable Energy Module
2.5.1 Solar Module—Physical Model
2.6 Summary
2.7 Review Questions
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Basics of PSpice Simulation Tool 3.1 Introduction to PSpice
3.1.1 Nomenclature, File Structure
3.1.2 Model Libraries-
Model Library Configuration
3.1.3 Way to Scrutiny -
DC Sweep
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Transient Analysis
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AC Sweep Analysis
3.2 Designing and Simulation of Power IGBTs
3.2.1 IGBT Models
3.2.2 Characteristics of IGBT
3.2.3 PSpice Model of IGBT
3.3 Design and Simulation of TRIAC
3.3.1 Introduction to TRIAC
3.3.2 I–V Characteristics of TRIAC
3.3.3 I–V Characteristics of TRIAC Using PSpice
3.4 Summary
3.5 Review Questions
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Multisim 4.1 Multisim Introduction
4.1.1 Menu Bars-
Standard Toolbar
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Main Toolbar
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Simulation Toolbar
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View Toolbar
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Elements Menu Bar
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Graphic Annotation Toolbar
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Instruments Toolbar
4.1.2 Building Blocks
4.1.3 Electrical Rule Check
4.1.4 Running the Simulation Process -
Intuitive Elements
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Components Tolerance
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Start, Pause, or Stop Simulation
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Simulation Run Indicator
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Speed of the Simulation
4.1.5 Plotting -
Grapher
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Working with Graphs—Legends and Grids
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Cursors
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Zoom and Restore
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Traces
4.1.6 Converters—Using Multisim Model Maker -
Boost Converter Design
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Buck Converter: Voltage Mode PWM Control
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Buck-Boost Converter: Current Mode PWM Control
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Flyback Converter: Voltage Mode PWM Control
4.1.7 Clipper and Clamper Design -
Clamper Applications Circuit
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Precision Clipper
4.1.8 Filter Design -
First-Order Low-Pass Filter
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Active Bandpass Filter
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High-Pass Active Filter
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Basic Differential Amplifier
4.2 Circuits Design Using Multisim Model Maker
4.2.1 Amplifier Design -
Class-A Amp
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Class-AB Amp
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Darlington Pair
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Two-Tier Common-Emitter Amp
4.3 Summary
4.4 Review Questions
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Printed Circuit Board Design Tool—DesignSpark 5.1 Introduction to Printed Circuit Board Design Software
5.1.1 Overview of Printed Circuit Board Design Software
5.1.2 Parts of the Printed Circuit Board
5.1.3 Printed Circuit Board Design Flow
5.1.4 Design Guidelines
5.2 Printed Circuit Board Design in DesignSpark
5.2.1 Overview of DesignSpark
5.2.2 User Interface and Management of DesignSpark Work Environment
5.2.3 Schematic Capture
5.2.4 Component Creation
5.2.5 Netlisting
5.2.6 Component Placement
5.2.7 Wiring
5.2.8 Power and Ground Plane Creation
5.2.9 Checking the Design
5.2.10 Gerber Data Output for Manufacturing
5.3 Sample Printed Circuit Board Design—Schmitt Trigger
5.3.1 Project Creation
5.3.2 Library Creation
5.3.3 Schematic Design
5.3.4 Printed Circuit Board Layout
5.3.5 Manufacturing File Output
5.4 Summary
5.5 Review Questions -
Simulation of Hydraulic and Pneumatic Valves: Programmable Logic Controller 6.1 Introduction to Programmable Logic Controller
6.1.1 Programmable Logic Controller and Its Basic Structure
6.1.2 History of the Programmable Logic Controller
6.1.3 Birth of the Programmable Logic Controller Solution
6.1.4 Applications, Disadvantages, and Advantages-
Applications
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Disadvantages
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Advantages
6.1.5 Major Types of Industrial Control Systems
6.1.6 Hardware Components of a Programmable Logic Controller System -
Memory
6.2 Ladder Logic
6.2.1 Origins of Ladder Logic: Relay Logic
6.2.2 Structure of Ladder Logic
6.2.3 Similarities with Ladder Diagrams
6.2.4 Execution of Ladder Logic
6.2.5 Ladder Logic Instructions: The Basics -
Normally Open Contact of PLC
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PLC Timers
6.3 Electropneumatics Using Programmable Logic Controller
6.3.1 Introduction
6.3.2 Seven Basic Electrical Devices -
Push-Button Switches
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Limit Switches
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Pressure Switches
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Solenoids
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Relays
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Timer/Time Delay Relays
6.4 Electro-Pneumatics Circuits -
Control of System with Timed Response
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Control of Double-Acting Cylinder
6.5 Summary
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Tags: Ashok Kumar, Indragandhi, Uma Maheswari, Electrical Systems, Theory and Practice