Modern Control Engineering (5th Edition)
β Katsuhiko Ogata
π Library
π
2009
π Prentice Hall
π English
β¦ LIBER β¦
π
Modern Control Engineering (5th Edition)
β Scribed by Katsuhiko Ogata
- Publisher
- Prentice Hall
- Year
- 2009
- Tongue
- English
- Leaves
- 905
- Series
- Prentice-Hall electrical engineering series. Instrumentation and controls series
- Edition
- 5th
- Category
- Library
β¬ Acquire This Volume
No coin nor oath required. For personal study only.
β¦ Synopsis
For senior or graduate-level students taking a first course in Control Theory (in departments of Mechanical, Electrical, Aerospace, and Chemical Engineering). Β A comprehensive, senior-level textbook for control engineering. Β Ogataβs Modern Control Engineering, 5/e, offers the comprehensive coverage of continuous-time control systems that all senior students must have, including frequency response approach, root-locus approach, and state-space approach to analysis and design of control systems. The text provides a gradual development of control theory, shows how to solve all computational problems with MATLAB, and avoids highly mathematical arguments. A wealth of examples and worked problems are featured throughout the text. Β The new edition includes improved coverage of Root-Locus Analysis (Chapter 6) and Frequency-Response Analysis (Chapter 8). The author has also updated and revised many of the worked examples and end-of-chapter problems. This text is ideal for control systems engineers.
β¦ Table of Contents
Cover������������......Page 1
Title Page�����������������......Page 2
Copyright����������������......Page 3
Contents......Page 4
Preface......Page 10
1β1 Introduction......Page 12
1β2 Examples of Control Systems......Page 15
1β3 Closed-Loop Control Versus Open-Loop Control......Page 18
1β4 Design and Compensation of Control Systems......Page 20
1β5 Outline of the Book......Page 21
2β1 Introduction......Page 24
2β2 Transfer Function and Impulse-Response Function......Page 26
2β3 Automatic Control Systems......Page 28
2β4 Modeling in State Space......Page 40
2β5 State-Space Representation of Scalar Differential Equation Systems......Page 46
2β6 Transformation of Mathematical Models with MATLAB......Page 50
2β7 Linearization of Nonlinear Mathematical Models......Page 54
Example Problems and Solutions......Page 57
Problems......Page 71
3β2 Mathematical Modeling of Mechanical Systems......Page 74
3β3 Mathematical Modeling of Electrical Systems......Page 83
Example Problems and Solutions......Page 97
Problems......Page 108
4β1 Introduction......Page 111
4β2 Liquid-Level Systems......Page 112
4β3 Pneumatic Systems......Page 117
4β4 Hydraulic Systems......Page 134
4β5 Thermal Systems......Page 147
Example Problems and Solutions......Page 151
Problems......Page 163
5β1 Introduction......Page 170
5β2 First-Order Systems......Page 172
5β3 Second-Order Systems......Page 175
5β4 Higher-Order Systems......Page 190
5β5 Transient-Response Analysis with MATLAB......Page 194
5β6 Routhβs Stability Criterion......Page 223
5β7 Effects of Integral and Derivative Control Actions on System Performance......Page 229
5β8 Steady-State Errors in Unity-Feedback Control Systems......Page 236
Example Problems and Solutions......Page 242
Problems......Page 274
6β1 Introduction......Page 280
6β2 Root-Locus Plots......Page 281
6β3 Plotting Root Loci with MATLAB......Page 301
6β4 Root-Locus Plots of Positive Feedback Systems......Page 314
6β5 Root-Locus Approach to Control-Systems Design......Page 319
6β6 Lead Compensation......Page 322
6β7 Lag Compensation......Page 332
6β8 LagβLead Compensation......Page 341
6β9 Parallel Compensation......Page 353
Example Problems and Solutions......Page 358
Problems......Page 405
7β1 Introduction......Page 409
7β2 Bode Diagrams......Page 414
7β3 Polar Plots......Page 438
7β4 Log-Magnitude-versus-Phase Plots......Page 454
7β5 Nyquist Stability Criterion......Page 456
7β6 Stability Analysis......Page 465
7β7 Relative Stability Analysis......Page 473
7β8 Closed-Loop Frequency Response of Unity-Feedback Systems......Page 488
7β9 Experimental Determination of Transfer Functions......Page 497
7β10 Control Systems Design by Frequency-Response Approach......Page 502
7β11 Lead Compensation......Page 504
7β12 Lag Compensation......Page 513
7β13 LagβLead Compensation......Page 522
Example Problems and Solutions......Page 532
Problems......Page 572
8β1 Introduction......Page 578
8β2 ZieglerβNichols Rules for Tuning PID Controllers......Page 579
8β3 Design of PID Controllers with Frequency-Response Approach......Page 588
8β4 Design of PID Controllers with Computational Optimization Approach......Page 594
8β5 Modifications of PID Control Schemes......Page 601
8β6 Two-Degrees-of-Freedom Control......Page 603
8β7 Zero-Placement Approach to Improve Response Characteristics......Page 606
Example Problems and Solutions......Page 625
Problems......Page 652
9β1 Introduction......Page 659
9β2 State-Space Representations of Transfer-Function Systems......Page 660
9β3 Transformation of System Models with MATLAB......Page 667
9β4 Solving the Time-Invariant State Equation......Page 671
9β5 Some Useful Results in Vector-Matrix Analysis......Page 679
9β6 Controllability......Page 686
9β7 Observability......Page 693
Example Problems and Solutions......Page 699
Problems......Page 731
10β1 Introduction......Page 733
10β2 Pole Placement......Page 734
10β3 Solving Pole-Placement Problems with MATLAB......Page 746
10β4 Design of Servo Systems......Page 750
10β5 State Observers......Page 762
10β6 Design of Regulator Systems with Observers......Page 789
10β7 Design of Control Systems with Observers......Page 797
10β8 Quadratic Optimal Regulator Systems......Page 804
10β9 Robust Control Systems......Page 817
Example Problems and Solutions......Page 828
Problems......Page 866
Appendix A: Laplace Transform Tables......Page 870
Appendix B: Partial-Fraction Expansion......Page 878
Appendix C: Vector-Matrix Algebra......Page 885
References......Page 893
B......Page 897
D......Page 898
I......Page 899
M......Page 900
P......Page 902
R......Page 903
T......Page 904
Z......Page 905
β¦ Subjects
ΠΠ²ΡΠΎΠΌΠ°ΡΠΈΠ·Π°ΡΠΈΡ;Π’Π΅ΠΎΡΠΈΡ Π°Π²ΡΠΎΠΌΠ°ΡΠΈΡΠ΅ΡΠΊΠΎΠ³ΠΎ ΡΠΏΡΠ°Π²Π»Π΅Π½ΠΈΡ (Π’ΠΠ£);ΠΠ½ΠΈΠ³ΠΈ Π½Π° ΠΈΠ½ΠΎΡΡΡΠ°Π½Π½ΡΡ ΡΠ·ΡΠΊΠ°Ρ ;
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