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Automatic Control Systems (Record no. 357)

MARC details
000 -LEADER
fixed length control field 07474nam a2200253Ia 4500
001 - CONTROL NUMBER
control field 0001112
003 - CONTROL NUMBER IDENTIFIER
control field OSt
005 - DATE AND TIME OF LATEST TRANSACTION
control field 20190121120744.0
008 - FIXED-LENGTH DATA ELEMENTS--GENERAL INFORMATION
fixed length control field 170602s9999 xx 000 0 und d
020 ## - INTERNATIONAL STANDARD BOOK NUMBER
International Standard Book Number 9788126552337
028 ## - PUBLISHER NUMBER
Qualifying information 2016
Source Allied Informatics, Jaipur
040 ## - CATALOGING SOURCE
Language of cataloging English
Original cataloging agency BSDU
Transcribing agency BSDU
082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER
Classification number 629.83
Item number GOL
100 ## - MAIN ENTRY--PERSONAL NAME
Personal name Golnaraghi, Farid
245 #0 - TITLE STATEMENT
Title Automatic Control Systems
250 ## - EDITION STATEMENT
Edition statement 9th
260 ## - PUBLICATION, DISTRIBUTION, ETC.
Name of publisher, distributor, etc. Wiley India Pvt. Ltd. India
Place of publication, distribution, etc. New Delhi
Date of publication, distribution, etc. 2015,c2010
300 ## - PHYSICAL DESCRIPTION
Extent 786
500 ## - GENERAL NOTE
General note Automatic Control Systems provides engineers with a fresh new controls book that places special emphasis on mechatronics. It follows a revolutionary approach by actually including a physical lab. In addition, readers will find authoritative coverage of modern design tools and examples. Current mechatronics applications build motivation to learn the material. Extensive use of virtual lab software is also integrated throughout the chapters. Engineer gains a strong understanding the control systems with the help of modern examples and exercises.
504 ## - BIBLIOGRAPHY, ETC. NOTE
Bibliography, etc. note Contents:<br/>Preface.<br/><br/> <br/><br/>Chapter 1: Introduction.<br/><br/>1.1 Introduction.<br/><br/>1.2 What Is Feedback and What Are Its Effects?<br/><br/>1.3 Types of Feedback Control Systems.<br/><br/>1.4 Summary.<br/><br/> <br/><br/>Chapter 2: Mathematical Foundation.<br/><br/>2.1 Complex-Variable Concept.<br/><br/>2.2 Frequency-Domain Plots.<br/><br/>2.3 Introduction to Differential Equations.<br/><br/>2.4 Laplace Transform.<br/><br/>2.5 Inverse Laplace Transform by Partial-Fraction Expansion.<br/><br/>2.6 Application of the Laplace Transform to the Solution of Linear Ordinary Differential Equations.<br/><br/>2.7 Impulse Response and Transfer Functions of Linear Systems.<br/><br/>2.8 Stability of Linear Control Systems.<br/><br/>2.9 Bounded-Input, Bounded-Output.<br/><br/>2.10 Relationship between Characteristic Equation Roots and Stability.<br/><br/>2.11 Zero-Input and Asymptotic Stability of Continuous-Data Systems.<br/><br/>2.12 Methods of Determining Stability.<br/><br/>2.13. Routh-Hurwitz Criterion.<br/><br/>2.14 MATLAB Tools and Case Studies.<br/><br/>2.15 Summary.<br/><br/> <br/><br/>Chapter 3: Block Diagrams and Signal-Flow Graphs.<br/><br/>3.1 Block Diagrams.<br/><br/>3.2 Signal-Flow Graphs (SFGs).<br/><br/>3.3 MATLAB Tools and Case Studies.<br/><br/>3.4 Summary.<br/><br/> <br/><br/>Chapter 4: Theoretical Foundation and Background Material: Modeling of Dynamic Systems.<br/><br/>4.1 Introduction to Modeling of Mechanical Systems.<br/><br/>4.2 Introduction to Modeling of Simple Electrical Systems.<br/><br/>4.3 Modeling of Active Electrical Elements: Operational Amplifiers.<br/><br/>4.4 Introduction of Modeling of Thermal Systems.<br/><br/>4.5 Introduction of Modeling of Fluid Systems.<br/><br/>4.6 Sensors and Encoders in Control Systems.<br/><br/>4.7 DC Motors in Control Systems.<br/><br/>4.8 Systems with Transportation Lags.<br/><br/>4.9 Linearization of Nonlinear Systems.<br/><br/>4.10 Analogies.<br/><br/>4.11 Case Studies.<br/><br/>4.12 MATLAB Tools.<br/><br/>4.13 Summary.<br/><br/> <br/><br/>Chapter 5: Time-Domain Analysis of Control Systems.<br/><br/>5.1 Time Response of Continuous-Data Systems: Introduction.<br/><br/>5.2 Typical Test Signals for the Time Response of Control Systems.<br/><br/>5.3 The Unit-Step Response and Time-Domain Specification.<br/><br/>5.4 Steady-State Error.<br/><br/>5.5 Time Response of a Prototype First-Order System.<br/><br/>5.6 Transient Response of a Prototype Second-Order System.<br/><br/>5.7 Speed and Position Control of a DC Moto.<br/><br/>5.8 Time-Domain Analysis of a Position-Control System.<br/><br/>5.9 Basic Control Systems and Effects of Adding Poles and Zeros to Transfer Functions.<br/><br/>5.10 Dominant Poles and Zeros of Transfer Functions.<br/><br/>5.11 Basic Control Systems Utilizing Addition of Poles and Zeros.<br/><br/>5.12. MATLAB Tools.<br/><br/>5.13 Summary.<br/><br/> <br/><br/>Chapter 6: The Control Lab.<br/><br/>6.1 Introduction.<br/><br/>6.2 Description of the Virtual Experimental System.<br/><br/>6.3 Description of SIMLab and Virtual Lab Software.<br/><br/>6.4 Simulation and Virtual Experiments.<br/><br/>6.5 Design Project 1--Robotic Arm.<br/><br/>6.6 Design Project 2--Quarter-Car Model.<br/><br/>6.7 Summary.<br/><br/> <br/><br/>Chapter 7: Root Locus Analysis.<br/><br/>7.1 Introduction.<br/><br/>7.2 Basic Properties of the Root Loci (RL).<br/><br/>7.3 Properties of the Root Loci.<br/><br/>7.4 Design Aspects of the Root Loci.<br/><br/>7.5 Root Contours (RC): Multiple-Parameter Variation.<br/><br/>7.6 MATLAB Tools and Case Studies.<br/><br/>7.7 Summary.<br/><br/> <br/><br/>Chapter 8: Frequency-Domain Analysis.<br/><br/>8.1 Introduction.<br/><br/>8.2 M . W and Bandwidth of the Prototype Second-Order System.<br/><br/>8.3 Effects of adding a Zero to the Forward-Path Transfer Function.<br/><br/>8.4 Effects of adding a Pole to the Forward-Path Transfer Function.<br/><br/>8.5 Nyquist Stability Criterion: Fundamentals.<br/><br/>8.6 Nyquist Criterion for Systems with Minimum-Phase Transfer Functions.<br/><br/>8.7 Relation between the Root Loci and the Nyquist Plot.<br/><br/>8.8 Illustrative Examples: Nyquist Criterion for Minimum-Phase Transfer.<br/><br/>8.9 Effects of Adding Poles and Zeros to L(s) on the Shape of the Nyquist Plot.<br/><br/>8.10 Relative Stability: Gain Margin (GM).<br/><br/>8.11 Stability Analysis with the Bode Plot.<br/><br/>8.12 Relative Stability Related to the Slope of the Magnitude Curve of the Bode Plot.<br/><br/>8.13 Stability Analysis with the Magnitude-Phase Plot.<br/><br/>8.14 Constant-M Loci in the Magnitude-Phase Plane: The Nichols Chart Applied to Nonunity-Feedback Systems.<br/><br/>8.15 Nichols Chart Applied to Nonunity-Feedback Systems.<br/><br/>8.16 Sensitivity Studies in the Frequency Domain.<br/><br/>8.17 MATLAB Tools and Case Studies.<br/><br/>8.18 Summary.<br/><br/> <br/><br/>Chapter 9: Design of Control Systems.<br/><br/>9.1 Introduction.<br/><br/>9.2 Design with the PD Controller.<br/><br/>9.3 Design with the PI Controller.<br/><br/>9.4 Design with the PID Controller.<br/><br/>9.5 Design with Phase-Lead Controller.<br/><br/>9.6 Design with Phase-Lag Controller.<br/><br/>9.7 Design with Lead-Lag Controller.<br/><br/>9.8 Pole-Zero-Cancellation Design: Notch Filter.<br/><br/>9.9 Forward and Feed forward Controllers.<br/><br/>9.10 Design of Robust Control Systems.<br/><br/>9.11 Minor-Loop Feedback Control.<br/><br/>9.12 A Hydraulic Control System.<br/><br/>9.13 Controller Design.<br/><br/>9.14. MATLAB Tools and Case Studies.<br/><br/>9.15 Plotting Tutorial.<br/><br/>9.16 Summary.<br/><br/> <br/><br/>Chapter 10: State Variable Analysis.<br/><br/>10.1 Introduction.<br/><br/>10.2 Block Diagrams, Transfer Functions and State Diagrams.<br/><br/>10.3 Vector-Matrix Representation of State Equations.<br/><br/>10.4 State-Transition Matrix.<br/><br/>10.5 State-Transition Equation.<br/><br/>10.6 Relationship between State Equations and High-Order Differential Equations.<br/><br/>10.7 Relationship between State Equations and Transfer Functions.<br/><br/>10.8 Characteristic Equations, Eigenvalues and Eigenvectors.<br/><br/>10.9 Similarity Transformation.<br/><br/>10.10 Decompositions of Transfer Functions.<br/><br/>10.11 Controllability of Control Systems.<br/><br/>10.12 Observability of Linear Systems.<br/><br/>10.13 Relationship among Controllability, Observability and Transfer Functions.<br/><br/>10.14 Invariant Theorems on Controllability and Observability.<br/><br/>10.15 Case Study: Magnetic-Ball Suspension System.<br/><br/>10.16 State-Feedback Control.<br/><br/>10.17 Pole-Placement Design through State Feedback.<br/><br/>10.18 State Feedback with Integral Control.<br/><br/>10.19 MATLAB Tools and Case Studies.<br/><br/>10.20 Summary.<br/><br/> <br/><br/>Index.<br/><br/>Appendix A: Elementary Matrix Theory and Algebra.<br/><br/>Appendix B: Difference Equations.<br/><br/>Appendix C: Laplace Transform Table.<br/><br/>Appendix D: z-Transform Table.<br/><br/>Appendix E: Properties and Construction of the Root Loci.<br/><br/>Appendix F: General Nyquist Criterion.<br/><br/>Appendix G: ACSYS 2008: Description of the Software.<br/><br/>Appendix H: Discrete-Data Control Systems.
650 ## - SUBJECT ADDED ENTRY--TOPICAL TERM
Topical term or geographic name entry element Electronics
700 ## - ADDED ENTRY--PERSONAL NAME
Personal name Kuo, Benjamin C
942 ## - ADDED ENTRY ELEMENTS (KOHA)
Source of classification or shelving scheme Dewey Decimal Classification
Koha item type Books
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Withdrawn status Lost status Source of classification or shelving scheme Damaged status Not for loan Home library Current library Date acquired Cost, normal purchase price Total Checkouts Full call number Barcode Date last seen Date last checked out Cost, replacement price Price effective from Koha item type
    Dewey Decimal Classification     BSDU Knowledge Resource Center, Jaipur BSDU Knowledge Resource Center, Jaipur 12/01/2016 659.00 1 629.83 GOL 001112 10/06/2022 09/19/2022 659.00 06/02/2017 Books
    Dewey Decimal Classification     BSDU Knowledge Resource Center, Jaipur BSDU Knowledge Resource Center, Jaipur 12/01/2016 659.00   629.83 GOL 001113 02/12/2020   659.00 06/02/2017 Books