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    Control Systems Engineering 8e

    Yayınevi : Wiley
    Yazar : Norman S. Nise
    ISBN :9781119590132
    Sayfa Sayısı :688
    Baskı Sayısı :8
    Ebatlar :20.00 X 25.00
    Basım Yılı :2019
    Fiyat ve temin süresi için lütfen bize ulaşın

    Bu ürün için iade seçeneği bulunmamaktadır.

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    Tahmini Kargoya Veriliş Zamanı: 6-8 hafta

    Control Systems Engineering 8e

    Highly regarded for its accessibility and focus on practical applications, Control Systems Engineering offers students a comprehensive introduction to the design and analysis of feedback systems that support modern technology. Going beyond theory and abstract mathematics to translate key concepts into physical control systems design, this text presents real-world case studies, challenging chapter questions, and detailed explanations with an emphasis on computer aided design. Abundant illustrations facilitate comprehension, with over 800 photos, diagrams, graphs, and tables designed to help students visualize complex concepts. Multiple experiment formats demonstrate essential principles through hypothetical scenarios, simulations, and interactive virtual models, while Cyber Exploration Laboratory Experiments allow students to interface with actual hardware through National Instruments’ myDAQ for real-world systems testing. This emphasis on practical applications has made it the most widely adopted text for core courses in mechanical, electrical, aerospace, biomedical, and chemical engineering. Now in its eighth edition, this top-selling text continues to offer in-depth exploration of up-to-date engineering practices. 

    PREFACE, vii

    1 INTRODUCTION, 1
    1.1 Introduction, 2
    1.2 A History of Control Systems, 4
    1.3 System Configurations, 6
    1.4 Analysis and Design Objectives, 9
    Case Study, 11
    1.5 The Design Process, 14
    1.6 Computer-Aided Design, 19
    1.7 The Control Systems Engineer, 20
    Summary, 21
    Review Questions, 22
    Cyber Exploration Laboratory, 22
    Bibliography, 23

    2 MODELING IN THE FREQUENCY DOMAIN, 25
    2.1 Introduction, 26
    2.2 Laplace Transform Review, 27
    2.3 The Transfer Function, 36
    2.4 Electrical Network Transfer Functions, 39
    2.5 Translational Mechanical System Transfer Functions, 53
    2.6 Rotational Mechanical System Transfer Functions, 61
    2.7 Transfer Functions for Systems with Gears, 65
    2.8 Electromechanical System Transfer Functions, 69
    2.9 Electric Circuit Analogs, 75
    2.10 Nonlinearities, 78
    2.11 Linearization, 79
    Case Studies, 84
    Summary, 87
    Review Questions, 87
    Cyber Exploration Laboratory, 88

    Hardware Interface Laboratory, 91
    Bibliography, 93

    3. MODELING IN THE TIME DOMAIN, 95
    3.1 Introduction, 96
    3.2 Some Observations, 96
    3.3 The General State-Space Representation, 100
    3.4 Applying the State-Space Representation, 102
    3.5 Converting a Transfer Function to State Space, 110
    3.6 Converting from State Space to a Transfer Function, 116
    3.7 Linearization, 118
    Case Studies, 121
    Summary, 125
    Review Questions, 126
    Cyber Exploration Laboratory, 126
    Bibliography, 128

    4 TIME RESPONSE, 130
    4.1 Introduction, 131
    4.2 Poles, Zeros, and System Response, 131
    4.3 First-Order Systems, 135
    4.4 Second-Order Systems: Introduction, 137
    4.5 The General Second-Order System, 142
    4.6 Underdamped Second-Order Systems, 146
    4.7 System Response with Additional Poles, 155
    4.8 System Response with Zeros, 159
    4.9 Effects of Nonlinearities upon Time Response, 165
    4.10 Laplace Transform Solution of State Equations, 167
    4.11 Time Domain Solution of State Equations, 171
    Case Studies, 175 Summary, 181
    Review Questions, 182
    Cyber Exploration Laboratory, 183
    Hardware Interface Laboratory, 186
    Bibliography, 192

    5. REDUCTION OF MULTIPLE SUBSYSTEMS, 194
    5.1 Introduction, 195
    5.2 Block Diagrams, 195
    5.3 Analysis and Design of Feedback Systems, 204
    5.4 Signal-Flow Graphs, 207
    5.5 Mason’s Rule, 210
    5.6 Signal-Flow Graphs of State Equations, 213
    5.7 Alternative Representations in State Space, 215
    5.8 Similarity Transformations, 224
    Case Studies, 231
    Summary, 237
    Review Questions, 237
    Cyber Exploration Laboratory, 238
    Bibliography, 240

    6. STABILITY, 242
    6.1Introduction, 243
    6.2Routh-Hurwitz Criterion, 246
    6.3Routh-Hurwitz Criterion: Special Cases, 248
    6.4Routh-Hurwitz Criterion: Additional Examples, 254
    6.5 Stability in State Space, 261
    Case Studies, 264
    Summary, 266
    Review Questions, 266
    Cyber Exploration Laboratory, 267
    Bibliography, 268

    7. STEADY-STATE ERRORS, 270
    7.1 Introduction, 271
    7.2 Steady-State Error for Unity Feedback Systems, 274
    7.3 Static Error Constants and System Type, 280
    7.4 Steady-State Error Specifications, 283
    7.5 Steady-State Error for Disturbances, 286
    7.6 Steady-State Error for Nonunity- Feedback Systems, 288
    7.7 Sensitivity, 291
    7.8 Steady-State Error for Systems in State Space, 294
    Case Studies, 297 Summary, 300
    Review Questions, 301
    Cyber Exploration Laboratory, 302 Bibliography, 303

    8 ROOT LOCUS TECHNIQUES, 305
    8.1 Introduction, 306
    8.2 Defining the Root Locus, 310
    8.3 Properties of the Root Locus, 312
    8.4 Sketching the Root Locus, 314
    8.5 Refining the Sketch, 319
    8.6 An Example, 328
    8.7Transient Response Design via Gain Adjustment, 331
    8.8 Generalized Root Locus, 335
    8.9 Root Locus for Positive-Feedback Systems, 337
    8.10 Pole Sensitivity, 339
    Case Studies, 341
    Summary, 346
    Review Questions, 347
    Cyber Exploration Laboratory, 347
    Hardware Interface Laboratory, 349
    Bibliography, 356

    9. DESIGN VIA ROOT LOCUS, 358
    9.1 Introduction, 359
    9.2 Improving Steady-State Error via Cascade Compensation, 362
    9.3 Improving Transient Response via Cascade Compensation, 371
    9.4 Improving Steady-State Error and Transient Response, 383
    9.5 Feedback Compensation, 396
    9.6 Physical Realization of Compensation, 404
    Case Studies, 409
    Summary, 413
    Review Questions, 414
    Cyber Exploration Laboratory, 415
    Hardware Interface Laboratory, 417
    Bibliography, 419

    10. FREQUENCY RESPONSE TECHNIQUES, 421
    10.1 Introduction, 422
    10.2 Asymptotic Approximations: Bode Plots, 427
    10.3 Introduction to the Nyquist Criterion, 446
    10.4 Sketching the Nyquist Diagram, 451
    10.5 Stability via the Nyquist Diagram, 456
    10.6 Gain Margin and Phase Margin via the Nyquist Diagram, 460
    10.7 Stability, Gain Margin, and Phase Margin via Bode Plots, 462
    10.8 Relation Between Closed-Loop Transient and Closed-Loop Frequency Responses, 466
    10.9 Relation Between Closed- and Open-Loop Frequency Responses, 469
    10.10 Relation Between Closed-Loop Transient and Open-Loop Frequency Responses, 474
    10.11 Steady-State Error Characteristics from Frequency Response, 478
    10.12 Systems with Time Delay, 482
    10.13 Obtaining Transfer Functions Experimentally, 487
    Case Study, 491
    Summary, 492
    Review Questions, 493
    Cyber Exploration Laboratory, 494
    Bibliography, 496

    11. DESIGN VIA FREQUENCY RESPONSE, 498
    11.1 Introduction, 499
    11.2 Transient Response via Gain Adjustment, 500
    11.3 Lag Compensation, 503
    11.4 Lead Compensation, 508
    11.5 Lag-Lead Compensation, 514
    Case Studies, 523
    Summary, 525
    Review Questions, 525
    Cyber Exploration Laboratory, 526 Bibliography, 527

    12. DESIGN VIA STATE SPACE, 528
    12.1 Introduction, 529
    12.2 Controller Design, 530
    12.3 Controllability, 537
    12.4 Alternative Approaches to Controller Design, 540
    12.5 Observer Design, 546
    12.6 Observability, 553
    12.7 Alternative Approaches to Observer Design, 556
    12.8 Steady-State Error Design via Integral Control, 563
    Case Study, 567
    Summary, 572
    Review Questions, 573
    Cyber Exploration Laboratory, 574 Bibliography, 575

    13. DIGITAL CONTROL SYSTEMS, 577
    13.1 Introduction, 578
    13.2 Modeling the Digital Computer, 581
    13.3 The z-Transform, 584
    13.4 Transfer Functions, 589
    13.5 Block Diagram Reduction, 593
    13.6 Stability, 596
    13.7 Steady-State Errors, 603
    13.8 Transient Response on the z-Plane, 607
    13.9 Gain Design on the z-Plane, 609
    13.10 Cascade Compensation via the s-Plane, 612
    13.11 Implementing the Digital Compensator, 616
    Case Studies, 619 Summary, 623
    Review Questions, 624
    Cyber Exploration Laboratory, 625 Bibliography, 627
    Problems (Available in e-text for students) P-1

    APPENDIX A1 List of Symbols A-1.1
    APPENDIX A2 Antenna Azimuth Position Control System A-2.1
    APPENDIX A3 Unmanned Free-Swimming Submersible Vehicle A-3.1
    APPENDIX A4 Key Equations A-4.1

    GLOSSARY 628
    ANSWERS TO SELECTED PROBLEMS (Available in ext for students) 636 INDEX I-1
    APPENDIX B MATLAB Tutorial (Available in e-text for students)
    APPENDIX C Simulink Tutorial (Available in e-text for students)
    APPENDIX D LabVIEW Tutorial (Available in e-text for students)
    APPENDIX E MATLAB’s GUI Tools Tutorial (Available in e-text for students)
    APPENDIX F MATLAB’s Symbolic Math Toolbox Tutorial (Available in e-text for students)

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    Control Systems Engineering 8e

    Highly regarded for its accessibility and focus on practical applications, Control Systems Engineering offers students a comprehensive introduction to the design and analysis of feedback systems that support modern technology. Going beyond theory and abstract mathematics to translate key concepts into physical control systems design, this text presents real-world case studies, challenging chapter questions, and detailed explanations with an emphasis on computer aided design. Abundant illustrations facilitate comprehension, with over 800 photos, diagrams, graphs, and tables designed to help students visualize complex concepts. Multiple experiment formats demonstrate essential principles through hypothetical scenarios, simulations, and interactive virtual models, while Cyber Exploration Laboratory Experiments allow students to interface with actual hardware through National Instruments’ myDAQ for real-world systems testing. This emphasis on practical applications has made it the most widely adopted text for core courses in mechanical, electrical, aerospace, biomedical, and chemical engineering. Now in its eighth edition, this top-selling text continues to offer in-depth exploration of up-to-date engineering practices. 

    PREFACE, vii

    1 INTRODUCTION, 1
    1.1 Introduction, 2
    1.2 A History of Control Systems, 4
    1.3 System Configurations, 6
    1.4 Analysis and Design Objectives, 9
    Case Study, 11
    1.5 The Design Process, 14
    1.6 Computer-Aided Design, 19
    1.7 The Control Systems Engineer, 20
    Summary, 21
    Review Questions, 22
    Cyber Exploration Laboratory, 22
    Bibliography, 23

    2 MODELING IN THE FREQUENCY DOMAIN, 25
    2.1 Introduction, 26
    2.2 Laplace Transform Review, 27
    2.3 The Transfer Function, 36
    2.4 Electrical Network Transfer Functions, 39
    2.5 Translational Mechanical System Transfer Functions, 53
    2.6 Rotational Mechanical System Transfer Functions, 61
    2.7 Transfer Functions for Systems with Gears, 65
    2.8 Electromechanical System Transfer Functions, 69
    2.9 Electric Circuit Analogs, 75
    2.10 Nonlinearities, 78
    2.11 Linearization, 79
    Case Studies, 84
    Summary, 87
    Review Questions, 87
    Cyber Exploration Laboratory, 88

    Hardware Interface Laboratory, 91
    Bibliography, 93

    3. MODELING IN THE TIME DOMAIN, 95
    3.1 Introduction, 96
    3.2 Some Observations, 96
    3.3 The General State-Space Representation, 100
    3.4 Applying the State-Space Representation, 102
    3.5 Converting a Transfer Function to State Space, 110
    3.6 Converting from State Space to a Transfer Function, 116
    3.7 Linearization, 118
    Case Studies, 121
    Summary, 125
    Review Questions, 126
    Cyber Exploration Laboratory, 126
    Bibliography, 128

    4 TIME RESPONSE, 130
    4.1 Introduction, 131
    4.2 Poles, Zeros, and System Response, 131
    4.3 First-Order Systems, 135
    4.4 Second-Order Systems: Introduction, 137
    4.5 The General Second-Order System, 142
    4.6 Underdamped Second-Order Systems, 146
    4.7 System Response with Additional Poles, 155
    4.8 System Response with Zeros, 159
    4.9 Effects of Nonlinearities upon Time Response, 165
    4.10 Laplace Transform Solution of State Equations, 167
    4.11 Time Domain Solution of State Equations, 171
    Case Studies, 175 Summary, 181
    Review Questions, 182
    Cyber Exploration Laboratory, 183
    Hardware Interface Laboratory, 186
    Bibliography, 192

    5. REDUCTION OF MULTIPLE SUBSYSTEMS, 194
    5.1 Introduction, 195
    5.2 Block Diagrams, 195
    5.3 Analysis and Design of Feedback Systems, 204
    5.4 Signal-Flow Graphs, 207
    5.5 Mason’s Rule, 210
    5.6 Signal-Flow Graphs of State Equations, 213
    5.7 Alternative Representations in State Space, 215
    5.8 Similarity Transformations, 224
    Case Studies, 231
    Summary, 237
    Review Questions, 237
    Cyber Exploration Laboratory, 238
    Bibliography, 240

    6. STABILITY, 242
    6.1Introduction, 243
    6.2Routh-Hurwitz Criterion, 246
    6.3Routh-Hurwitz Criterion: Special Cases, 248
    6.4Routh-Hurwitz Criterion: Additional Examples, 254
    6.5 Stability in State Space, 261
    Case Studies, 264
    Summary, 266
    Review Questions, 266
    Cyber Exploration Laboratory, 267
    Bibliography, 268

    7. STEADY-STATE ERRORS, 270
    7.1 Introduction, 271
    7.2 Steady-State Error for Unity Feedback Systems, 274
    7.3 Static Error Constants and System Type, 280
    7.4 Steady-State Error Specifications, 283
    7.5 Steady-State Error for Disturbances, 286
    7.6 Steady-State Error for Nonunity- Feedback Systems, 288
    7.7 Sensitivity, 291
    7.8 Steady-State Error for Systems in State Space, 294
    Case Studies, 297 Summary, 300
    Review Questions, 301
    Cyber Exploration Laboratory, 302 Bibliography, 303

    8 ROOT LOCUS TECHNIQUES, 305
    8.1 Introduction, 306
    8.2 Defining the Root Locus, 310
    8.3 Properties of the Root Locus, 312
    8.4 Sketching the Root Locus, 314
    8.5 Refining the Sketch, 319
    8.6 An Example, 328
    8.7Transient Response Design via Gain Adjustment, 331
    8.8 Generalized Root Locus, 335
    8.9 Root Locus for Positive-Feedback Systems, 337
    8.10 Pole Sensitivity, 339
    Case Studies, 341
    Summary, 346
    Review Questions, 347
    Cyber Exploration Laboratory, 347
    Hardware Interface Laboratory, 349
    Bibliography, 356

    9. DESIGN VIA ROOT LOCUS, 358
    9.1 Introduction, 359
    9.2 Improving Steady-State Error via Cascade Compensation, 362
    9.3 Improving Transient Response via Cascade Compensation, 371
    9.4 Improving Steady-State Error and Transient Response, 383
    9.5 Feedback Compensation, 396
    9.6 Physical Realization of Compensation, 404
    Case Studies, 409
    Summary, 413
    Review Questions, 414
    Cyber Exploration Laboratory, 415
    Hardware Interface Laboratory, 417
    Bibliography, 419

    10. FREQUENCY RESPONSE TECHNIQUES, 421
    10.1 Introduction, 422
    10.2 Asymptotic Approximations: Bode Plots, 427
    10.3 Introduction to the Nyquist Criterion, 446
    10.4 Sketching the Nyquist Diagram, 451
    10.5 Stability via the Nyquist Diagram, 456
    10.6 Gain Margin and Phase Margin via the Nyquist Diagram, 460
    10.7 Stability, Gain Margin, and Phase Margin via Bode Plots, 462
    10.8 Relation Between Closed-Loop Transient and Closed-Loop Frequency Responses, 466
    10.9 Relation Between Closed- and Open-Loop Frequency Responses, 469
    10.10 Relation Between Closed-Loop Transient and Open-Loop Frequency Responses, 474
    10.11 Steady-State Error Characteristics from Frequency Response, 478
    10.12 Systems with Time Delay, 482
    10.13 Obtaining Transfer Functions Experimentally, 487
    Case Study, 491
    Summary, 492
    Review Questions, 493
    Cyber Exploration Laboratory, 494
    Bibliography, 496

    11. DESIGN VIA FREQUENCY RESPONSE, 498
    11.1 Introduction, 499
    11.2 Transient Response via Gain Adjustment, 500
    11.3 Lag Compensation, 503
    11.4 Lead Compensation, 508
    11.5 Lag-Lead Compensation, 514
    Case Studies, 523
    Summary, 525
    Review Questions, 525
    Cyber Exploration Laboratory, 526 Bibliography, 527

    12. DESIGN VIA STATE SPACE, 528
    12.1 Introduction, 529
    12.2 Controller Design, 530
    12.3 Controllability, 537
    12.4 Alternative Approaches to Controller Design, 540
    12.5 Observer Design, 546
    12.6 Observability, 553
    12.7 Alternative Approaches to Observer Design, 556
    12.8 Steady-State Error Design via Integral Control, 563
    Case Study, 567
    Summary, 572
    Review Questions, 573
    Cyber Exploration Laboratory, 574 Bibliography, 575

    13. DIGITAL CONTROL SYSTEMS, 577
    13.1 Introduction, 578
    13.2 Modeling the Digital Computer, 581
    13.3 The z-Transform, 584
    13.4 Transfer Functions, 589
    13.5 Block Diagram Reduction, 593
    13.6 Stability, 596
    13.7 Steady-State Errors, 603
    13.8 Transient Response on the z-Plane, 607
    13.9 Gain Design on the z-Plane, 609
    13.10 Cascade Compensation via the s-Plane, 612
    13.11 Implementing the Digital Compensator, 616
    Case Studies, 619 Summary, 623
    Review Questions, 624
    Cyber Exploration Laboratory, 625 Bibliography, 627
    Problems (Available in e-text for students) P-1

    APPENDIX A1 List of Symbols A-1.1
    APPENDIX A2 Antenna Azimuth Position Control System A-2.1
    APPENDIX A3 Unmanned Free-Swimming Submersible Vehicle A-3.1
    APPENDIX A4 Key Equations A-4.1

    GLOSSARY 628
    ANSWERS TO SELECTED PROBLEMS (Available in ext for students) 636 INDEX I-1
    APPENDIX B MATLAB Tutorial (Available in e-text for students)
    APPENDIX C Simulink Tutorial (Available in e-text for students)
    APPENDIX D LabVIEW Tutorial (Available in e-text for students)
    APPENDIX E MATLAB’s GUI Tools Tutorial (Available in e-text for students)
    APPENDIX F MATLAB’s Symbolic Math Toolbox Tutorial (Available in e-text for students)

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