Bücher online kaufen
Motion Control Systems
-0 %
Besorgungstitel - wird vorgemerkt | Lieferzeit: Besorgungstitel - Lieferbar innerhalb von 10 Werktagen I
Artikel-Nr:
9780470825730
Veröffentl:
2011
Erscheinungsdatum:
15.06.2011
Seiten:
376
Autor:
Asif Sabanovic
Gewicht:
832 g
Format:
250x175x25 mm
Sprache:
Englisch
Beschreibung:
Asif `abanovic is a Professor of Engineering and Natural Sciences at Sabanci University. Previously he has been with University of Sarajevo, Caltech, Keio University and Yamaguchi University. He was also Head of CAD/CAM and Robotics Department at Tubitak - MAM, Turkey. `abanovic has received Best Paper Awards from the IEEE, and his major fields of interest include power electronics, sliding mode control, motion control and mechatronics. He received a BS, MS, and PhD in Electrical Engineering from the University of Sarajevo, Bosnia and Herzegovina.
Kouhei Ohnishi a Professor of Systems Design Engineering at Keio University. His research interests include power electronics, mechatronics, motion control and haptics. Ohnishi received Best Paper Awards from the Institute of Electrical Engineers of Japan and the Japan Society for Precision Engineering. He also received Dr.-Ing. Eugene Mittelmann Achievement Award from the IEEE Industrial Electronics Society in 2004. Ohnishi holds a BE, ME, and PhD in Electrical Engineering from the University of Tokyo.
Kouhei Ohnishi a Professor of Systems Design Engineering at Keio University. His research interests include power electronics, mechatronics, motion control and haptics. Ohnishi received Best Paper Awards from the Institute of Electrical Engineers of Japan and the Japan Society for Precision Engineering. He also received Dr.-Ing. Eugene Mittelmann Achievement Award from the IEEE Industrial Electronics Society in 2004. Ohnishi holds a BE, ME, and PhD in Electrical Engineering from the University of Tokyo.
Motion Control Systems is concerned with design methods that support the never-ending requirements for faster and more accurate control of mechanical motion. The book presents material that is fundamental, yet at the same time discusses the solution of complex problems in motion control systems. Methods presented in the book are based on the authors' original research results. Mathematical complexities are kept to a required minimum so that practicing engineers as well as students with a limited background in control may use the book. It is unique in presenting know-how accumulated through work on very diverse problems into a comprehensive unified approach suitable for application in high demanding, high-tech products. Major issues covered include motion control ranging from simple trajectory tracking and force control, to topics related to haptics, bilateral control with and without delay in measurement and control channels, as well as control of nonredundant and redundant multibody systems.
* Provides a consistent unified theoretical framework for motion control design
* Offers graduated increase in complexity and reinforcement throughout the book
* Gives detailed explanation of underlying similarities and specifics in motion control
* Unified treatment of single degree-of-freedom and multibody systems
* Explains the fundamentals through implementation examples
* Based on classroom-tested materials and the authors' original research work
* Written by the leading researchers in sliding mode control (SMC) and disturbance observer (DOB)
* Accompanying lecture notes for instructors
* Simulink and MATLAB(r) codes available for readers to download
Motion Control Systemsis an ideal textbook for a course on motion control or as a reference for post-graduates and researchers in robotics and mechatronics. Researchers and practicing engineers will also find the techniques helpful in designing mechanical motion systems.
* Provides a consistent unified theoretical framework for motion control design
* Offers graduated increase in complexity and reinforcement throughout the book
* Gives detailed explanation of underlying similarities and specifics in motion control
* Unified treatment of single degree-of-freedom and multibody systems
* Explains the fundamentals through implementation examples
* Based on classroom-tested materials and the authors' original research work
* Written by the leading researchers in sliding mode control (SMC) and disturbance observer (DOB)
* Accompanying lecture notes for instructors
* Simulink and MATLAB(r) codes available for readers to download
Motion Control Systemsis an ideal textbook for a course on motion control or as a reference for post-graduates and researchers in robotics and mechatronics. Researchers and practicing engineers will also find the techniques helpful in designing mechanical motion systems.
Preface.
About the Authors.
PART ONE - BASICS OF DYNAMICS AND CONTROL.
1 Dynamics of Electromechanical Systems.
1.1 Basic Quantities.
1.2 Fundamental Concepts of Mechanical Systems.
1.3 Electric and Electromechanical Systems.
References.
Further Reading.
2 Control System Design.
2.1 Basic Concepts.
2.2 State Space Representation.
2.3 Dynamic Systems with Finite Time Convergence.
References.
Further Reading.
PART TWO - ISSUES IN MOTION CONTROL.
3 Acceleration Control.
3.1 Plant.
3.2 Acceleration Control.
3.3 Enforcing Convergence and Stability.
3.4 Trajectory Tracking.
References.
Further Reading.
4 Disturbance Observers.
4.1 Disturbance Model Based Observers.
4.2 Closed Loop Disturbance Observers.
4.3 Observer for Plant with Actuator.
4.4 Estimation of Equivalent Force and Equivalent Acceleration.
4.5 Functional Observers.
4.6 Dynamics of Plant with Disturbance Observer.
4.7 Properties of Measurement Noise Rejection.
4.8 Control of Compensated Plant.
References.
Further Reading.
5 Interactions and Constraints.
5.1 Interaction Force Control.
5.2 Constrained Motion Control.
5.3 Interactions in Functionally Related Systems.
References.
Further Reading.
6 Bilateral Control Systems.
6.1 Bilateral Control without Scaling.
6.2 Bilateral Control Systems in Acceleration Dimension.
6.3 Bilateral Systems with Communication Delay.
References.
Further Reading.
PART THREE - MULTIBODY SYSTEMS.
7 Configuration Space Control.
7.1 Independent Joint Control.
7.2 Vector Control in Configuration Space.
7.3 Constraints in Configuration Space.
7.4 Hard Constraints in Configuration Space.
References.
Further Reading.
8 Operational Space Dynamics and Control.
8.1 Operational Space Dynamics.
8.2 Operational Space Control.
References.
Further Reading.
9 Interactions in Operational Space.
9.1 Task-Constraint Relationship.
9.2 Force Control.
9.3 Impedance Control.
9.4 Hierarchy of Tasks.
References.
Further Reading.
Index.
About the Authors.
PART ONE - BASICS OF DYNAMICS AND CONTROL.
1 Dynamics of Electromechanical Systems.
1.1 Basic Quantities.
1.2 Fundamental Concepts of Mechanical Systems.
1.3 Electric and Electromechanical Systems.
References.
Further Reading.
2 Control System Design.
2.1 Basic Concepts.
2.2 State Space Representation.
2.3 Dynamic Systems with Finite Time Convergence.
References.
Further Reading.
PART TWO - ISSUES IN MOTION CONTROL.
3 Acceleration Control.
3.1 Plant.
3.2 Acceleration Control.
3.3 Enforcing Convergence and Stability.
3.4 Trajectory Tracking.
References.
Further Reading.
4 Disturbance Observers.
4.1 Disturbance Model Based Observers.
4.2 Closed Loop Disturbance Observers.
4.3 Observer for Plant with Actuator.
4.4 Estimation of Equivalent Force and Equivalent Acceleration.
4.5 Functional Observers.
4.6 Dynamics of Plant with Disturbance Observer.
4.7 Properties of Measurement Noise Rejection.
4.8 Control of Compensated Plant.
References.
Further Reading.
5 Interactions and Constraints.
5.1 Interaction Force Control.
5.2 Constrained Motion Control.
5.3 Interactions in Functionally Related Systems.
References.
Further Reading.
6 Bilateral Control Systems.
6.1 Bilateral Control without Scaling.
6.2 Bilateral Control Systems in Acceleration Dimension.
6.3 Bilateral Systems with Communication Delay.
References.
Further Reading.
PART THREE - MULTIBODY SYSTEMS.
7 Configuration Space Control.
7.1 Independent Joint Control.
7.2 Vector Control in Configuration Space.
7.3 Constraints in Configuration Space.
7.4 Hard Constraints in Configuration Space.
References.
Further Reading.
8 Operational Space Dynamics and Control.
8.1 Operational Space Dynamics.
8.2 Operational Space Control.
References.
Further Reading.
9 Interactions in Operational Space.
9.1 Task-Constraint Relationship.
9.2 Force Control.
9.3 Impedance Control.
9.4 Hierarchy of Tasks.
References.
Further Reading.
Index.
Lieferung vom Verlag mit leichten Qualitätsmängeln möglich