This significantly revised edition presents a broad introduction to Control Systems and balances new, modern methods with the more classical. It is an excellent text for use as a first course in Control Systems by undergraduate students in all branches of engineering and applied mathematics. The book contains: A comprehensive coverage of automatic control, integrating digital and computer control techniques and their implementations, the practical issues and problems in Control System design; the three-term PID controller, the most widely used controller in industry today; numerous in-chapter worked examples and end-of-chapter exercises. This second edition also includes an introductory guide to some more recent developments, namely fuzzy logic control and neural networks.
Author(s): Kevin Warwick
Series: Prentice Hall International Series in Systems and Control Engineering
Edition: 2nd ed
Publisher: Prentice Hall
Year: 1996
Language: English
Pages: 378
City: London
Cover......Page 1
An Introduction to Control Systems......Page 3
Contents......Page 9
Preface......Page 13
Preface to the Second Edition......Page 15
About the Author......Page 16
1.1 General introduction......Page 17
1.2 A concise history of control......Page 19
1.3 Open-loop control......Page 21
1.4 Closed-loop control......Page 22
1.5 Some examples of control systems......Page 24
1.6 Definitions of standard terminology......Page 26
Problems......Page 28
Further reading......Page 30
2.1 Introduction......Page 31
2.2 Transfer functions......Page 32
2.3 Block diagrams......Page 41
2.4 Physical system realizations......Page 48
2.5 Electromechanical devices......Page 58
2.6 Summary......Page 63
Problems......Page 64
Further reading......Page 70
3.1 Introduction......Page 72
3.2 Steady-state response......Page 73
3.3 Transient response......Page 81
3.4 Errors......Page 89
3.5 Servomechanisms......Page 100
3.6 Summary......Page 103
Problems......Page 104
Further reading......Page 108
4.1 Introduction......Page 109
4.2 The Routh-Hurwitz criterion......Page 111
4.3 Root loci construction......Page 118
4.4 Application of root loci......Page 131
4.5 Compensation based on a root locus......Page 141
Problems......Page 147
Further reading......Page 152
5.1 Introduction......Page 153
5.2 The Bode diagram......Page 155
5.3 Compensation using the Bode plot......Page 165
5.4 The Nyquist stability criterion......Page 175
5.5 Compensation using the Nyquist plot......Page 186
5.6 The Nichols chart......Page 193
5.7 Compensation using the Nichols chart......Page 200
5 8 Summary......Page 207
Problems......Page 208
Further reading......Page 211
6.1 Introduction......Page 213
6.2 State equations from transfer functions......Page 214
6.3 Solution to the state equations......Page 217
6.4 The characteristic equation......Page 221
6.5 Canonical forms......Page 225
6.6 Decomposition......Page 229
Problems......Page 232
Further reading......Page 236
7.1 introduction......Page 238
7.2 Controllability and observability......Page 239
7.3 Controllability and observability in transfer functions......Page 245
7.4 State variable feedback......Page 248
7.5 State estimation......Page 254
Problems......Page 259
Further reading......Page 264
8.2 Sampled data systems......Page 265
8.3 Stability analysis......Page 269
8.4 Digital compensation......Page 272
8.5 State variable forms......Page 277
8.6 Pole placement design......Page 280
Problems......Page 285
Further reading......Page 289
9.1 introduction......Page 290
9.2 System simulation......Page 291
9.3 Computer control......Page 295
9.4 Computer-aided design......Page 314
9.5 Summary......Page 318
Problems......Page 319
Further reading......Page 321
10.1 Introduction......Page 322
10.2 Proportional control......Page 323
10.3 Proportional + integral control......Page 328
10.4 PID control......Page 335
10.5 Summary......Page 345
Problems......Page 346
Further reading......Page 350
1. Matrix algebra......Page 351
2. Tables of common transforms......Page 359
3. Nonlinear systems......Page 362
4. Unity feedback loops......Page 371
Index......Page 375