Verfügbarkeit: Sliding mode control in electro-mechanical systems

Sliding mode control in electro-mechanical systems:

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Hauptverfasser:	Utkin, Vadim I. (VerfasserIn), Guldner, Jürgen (VerfasserIn), Shi, Jingxin (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Boca Raton [u.a.] CRC Press, Taylor & Francis 2009
Ausgabe:	2nd ed.
Schlagworte:	Control theory Electromechanical devices > Automatic control Sliding mode control Sliding-Mode Elektromechanisches Bauelement
Online-Zugang:	Klappentext Inhaltsverzeichnis
Beschreibung:	XVI, 485 S. graph. Darst.
ISBN:	9781420065602 1420065602

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adam_text	Electrical Engineering Interest in Sliding Mode Control (SMC) has grown rapidly since the first edition of this book was published. This second edition includes new results that have occurred in SMC throughout the past decade relating to both control design methodology and applications. In that time, SMC has continued to gain increasing importance as a universal design tool for the robust control of linear and nonlinear electro-mechanical systems. Its strengths result from its simple, flexible, and highly cost-effective approach to design and implementa¬ tion. Most importantly, SMC promotes inherent order reduction and allows for the direct incorporation of robustness against system uncertainties and disturbances. These quali¬ ties lead to dramatic improvements in stability and help enable the design of high- performance control systems at low cost. SMC is particularly useful for the design of electromechanical systems because of its discontinuous structure. In fact, where the hard¬ ware of many electromechanical systems (such as electric motors) prescribes discontin¬ uous inputs, SMC becomes the natural choice for direct implementation. Reflecting developments in the field over the past decade, this new edition of Sliding Mode Control in Electro-Mechanical Systems builds on the solid fundamentals presented in the first edition to promote a deeper understanding of the conventional SMC methodology. It examines new design principles in order to broaden the application potential of SMC. Written by three of the most respected experts in the field, including one of its origina¬ tors, this updated edition • Details new theoretical developments, including the suppression of the high- frequency oscillations that were considered the main obstacle to SMC imple¬ mentation • Complements new developments with cutting-edge design principles • Explores a wider range of applications, including cascade control of induction motors, control of multiphase power converters, new automotive applications • Adds new methods of power converter control, as well as a new chapter on high- order SMC for implementations with continuous control actions • Offers a simple and compact description of mathematical design principle This book provides a unique combination of theory, implementation issues, and examples of real-life applications reflective of the authors own industry-leading work in the devel¬ opment of robotics, hybrid automobiles, and other technological breakthroughs. Contents Preface ...................................................................................................................xiii Authors ...................................................................................................................xv Chapter 1 Introduction ......................................................................................1 1.1. Examples of Dynamic Systems with Sliding Modes ................................1 1.2. Sliding Modes in Relay and Variable Structure Systems .........................4 1.3. Multidimensional Sliding Modes ..............................................................10 1.4. Outline of Sliding Mode Control Methodology .....................................13 References ...............................................................................................................15 Chapter 2 Mathematical Background ...........................................................17 2.1. Problem Statement .......................................................................................17 2.2. Regularization ..............................................................................................20 2.3. Equivalent Control Method ........................................................................28 2.4. Physical Meaning of Equivalent Control .................................................31 2.5. Existence Conditions ...................................................................................33 References ...............................................................................................................40 Chapter 3 Design Concepts ............................................................................41 3.1. Introductory Example .................................................................................41 3.2. Decoupling ....................................................................................................42 3.3. Regular Form ................................................................................................46 3.4. Invariance .....................................................................................................49 3.5. Unit Control .................................................................................................51 3.6. Second-Order Sliding Mode Control ........................................................54 3.6.1. Preliminary Remarks ......................................................................54 3.6.2. Twisting Algorithm ........................................................................56 3.6.3. Super-Twisting Algorithm .............................................................60 References ...............................................................................................................62 Chapter 4 Sliding Mode Control of Pendulum Systems ..........................63 4.1. Design Methodology ...................................................................................63 4.1.1. Casezi ..............................................................................................64 4.1.2. Case 4.2..............................................................................................65 4.1.3. Case 4.3..............................................................................................65 4.1.4. Case 4.4..............................................................................................66 4.2. Cart Pendulum .............................................................................................67 4.3. Rotational Inverted Pendulum Model ......................................................72 4.4. Rotational Inverted Pendulum ...................................................................74 vii viii Contents 4.4.1. Control of the Inverted Pendulum ................................................74 4.4.2. Control of the Base Angle and Inverted Pendulum ....................77 4.5. Simulation and Experiment Results for Rotational Inverted Pendulum ......................................................................................................79 4.5.1. Stabilization of the Inverted Pendulum ........................................82 4.5.2. Stabilization of the Inverted Pendulum and the Base ..............................................................................................84 References ...............................................................................................................91 Chapter 5 Control of Linear Systems ............................................................93 5.1. Eigenvalue Placement ..................................................................................93 5.2. Invariant Systems .........................................................................................96 5.3. Sliding Mode Dynamic Compensators ....................................................97 5.4. Ackermann s Formula ...............................................................................103 5.4.1. Simulation Results .........................................................................107 5.5. Output Feedback Sliding Mode Control ................................................ Ill 5.6. Control of Time-Varying Systems ...........................................................117 References .............................................................................................................121 Chapter 6 Sliding Mode Observers ............................................................123 6.1. Linear Asymptotic Observers ..................................................................123 6.2. Observers for Linear Time-Invariant Systems .......................................125 6.3. Observers for Linear Time-Varying Systems .........................................126 6.3.1. Block-Observable Form .................................................................126 6.3.2. Observer Design ............................................................................129 6.3.3. Simulation Results .........................................................................131 6.3.4. Case 6.1: The System with Zero Disturbances ...........................133 6.3.5. Case 6.2: The System with Disturbances ....................................134 6.4. Observer for Linear Systems with Binary Output ................................135 6.4.1. Observer Design ............................................................................135 References ............................................................................................................138 Chapter 7 Integral Sliding Mode .................................................................139 7.1. Motivation ...................................................................................................139 7.2. Problem Statement .....................................................................................140 7.3. Design Principles .......................................................................................141 7.4. Perturbation and Uncertainty Estimation ..............................................143 7.5. Examples .....................................................................................................145 7.5.1. Linear Time-Invariant Systems ....................................................146 7.5.2. Control of Robot Manipulators ....................................................147 7.5.3. Pulse-Width Modulation for Electric Drives .............................150 7.5.4. Robust Current Control for Permanent-Magnet Synchronous Motors .....................................................................151 7.6. Summary .......................................................................................................157 References .............................................................................................................158 Contents ix Chapter 8 The Chattering Problem .............................................................159 8.1. Problem Analysis .......................................................................................159 8.1.1. Example System: Model ................................................................160 8.1.2. Example System: Ideal Sliding Mode ..........................................161 8.1.3. Example System: Causes of Chattering ......................................164 8.1.4. Describing Function Method for Chattering Analysis ............168 8.2. Boundary Layer Solution ..........................................................................172 8.3. Observer-Based Solution ..........................................................................175 8.4. Regular Form Solution ..............................................................................179 8.5. Disturbance Rejection Solution ................................................................183 8.6. State-Dependent Gain Method ................................................................187 8.7. Equivalent Control-Dependent Gain Method .......................................189 8.8. Multiphase Chattering Suppression .......................................................193 8.8.1. Problem Statement .........................................................................193 8.8.2. Design Principle .............................................................................196 8.9. Comparing the Different Solutions ........................................................201 References .............................................................................................................203 Chapter 9 Discrete-Time and Delay Systems ...........................................205 9.1. Introduction to Discrete-Time Systems ..................................................205 9.2. Discrete-Time Sliding Mode Concept .....................................................208 9.3. Linear Discrete-Time Systems with Known Parameters .....................212 9.4. Linear Discrete-Time Systems with Unknown Parameters .................214 9.5. Introduction to Systems with Delays and Distributed Systems .........216 9.6. Linear Systems with Delays .....................................................................217 9.7. Distributed Systems ...................................................................................218 9.8. Summary ....................................................................................................221 References .............................................................................................................222 Chapter 10 Electric Drives .............................................................................223 10.1. DC Motors ...................................................................................................224 10.1.1. Introduction ....................................................................................224 10.1.2. Model of the DC Motor ................................................................224 10.1.3. Current Control ..............................................................................225 10.1.4. Speed Control .................................................................................226 10.1.5. Integrated Structure for Speed Control ......................................227 10.1.6. Observer Design ............................................................................228 10.1.7. Speed Control with Reduced-Order Model ...............................232 10.1.8. Observer Design for Sensorless Control .....................................236 10.1.8.1. Estimation of the Shaft Speed .......................................236 10.1.8.2. Estimation of Load Torque ............................................238 10.1.9. Discussion .......................................................................................239 10.2. Permanent-Magnet Synchronous Motors ..............................................240 10.2.1. Introduction ....................................................................................240 10.2.2. Modeling of Permanent-Magnet Synchronous Motors ............243 Contents 10.2.3. Sliding Mode Current Control .....................................................249 10.2.3.1. First Method for Current Control .................................249 10.2.3.2. Second Method for Current Control ............................253 10.2.4. Speed Control .................................................................................258 10.2.5. Current Observer ...........................................................................261 10.2.6. Observer for Speed Sensorless Control ......................................264 10.2.6.1. Current Observer for EMF Components .....................265 10.2.6.2. Observer for EMF Components ....................................266 10.2.7. Discussion .......................................................................................269 10.3. Induction Motors ......................................................................................271 10.3.1. Introduction ....................................................................................271 10.3.2. Model of the Induction Motor ......................................................272 10.3.3. Rotor Flux Observer with Known Rotor Speed ........................278 10.3.3.1. Online Simulation of Rotor Flux Model .....................278 10.3.3.2. Sliding Mode Observer with Adjustable Rate of Convergence ...................................................................279 10.3.4. Simultaneous Observation of Rotor Flux and Rotor Speed .....................................................................................283 10.3.4.1. Analysis of Current Tracking ........................................284 10.3.4.2. Composite Observer-Controller Analysis ...................287 10.3.4.3. Simulation Results ..........................................................290 10.3.4.4. Experimental Results ......................................................290 10.3.5. Speed, Rotor Time Constant Observer, and Experimental Results ............................................................................................299 10.3.6 Direct Torque and Flux Control ..................................................306 10.3.6.1. Supplement: Cascaded Torque and Flux Control Via Phase Currents .........................................................316 10.4. Summary .....................................................................................................318 References .............................................................................................................319 Chapter 11 Power Converters .......................................................................321 11.1. DC/DC Converters ....................................................................................321 11.1.1. Bilinear Systems ............................................................................322 11.1.2. Direct Sliding Mode Control ........................................................324 11.1.2.1. Buck-Type DC/DC Converter ........................................325 11.1.2.2. Boost-Type DC/DC Converter ......................................327 11.1.3. Observer-Based Control ................................................................330 11.1.3.1. Observer-Based Control of Buck Converters ..............333 11.1.3.2. Observer-Based Control of Boost Converters .............337 11.1.4. Multiphase Converters .................................................................343 11.2. Boost-Type AC/DC Converters ................................................................352 11.2.1. Model of the Boost-Type AC/DC Converter .............................356 11.2.1.1. Model in Phase Coordinate Frame ...............................358 11.2.1.2. Model in (d, q) Coordinate Frame ...............................359 Contents xi 11.2.2. Control Problems...........................................................................362 11.2.2.1. Sliding Mode Current Control ......................................363 11.2.2.2. Output Voltage Regulation ............................................367 11.2.2.3. Simulation Results ..........................................................369 11.2.3. Observer for Sensorless Control ..................................................369 11.2.3.1. Current Observer for Source Phase Voltage ...............373 11.2.3.2. Observer for Source Voltage ..........................................374 11.2.3.3. Known Supply Frequency ............................................374 11.2.3.4. Unknown Supply Frequency ........................................375 11.2.3.5. Simulation Results ..........................................................376 11.3. DC/AC Converter ......................................................................................376 11.3.1. Dynamic Model ..............................................................................377 11.3.2. Control Design: Sliding Mode PWM ..........................................378 11.3.2.1. Lyapunov Approach .......................................................382 11.3.2.2. Decoupling Approach ....................................................383 11.3.2.3. Possible Applications of vn Control ..............................385 11.3.2.4. Simulation Results ..........................................................386 11.3.2.5. Experimental Results ......................................................387 11.4. Summary .....................................................................................................390 References .............................................................................................................396 Chapter 12 Advanced Robotics ....................................................................397 12.1. Dynamic Modeling ....................................................................................397 12.1.1. Generic Inerţial Dynamics ...........................................................398 12.1.2. Holonomic Robot Model ...............................................................399 12.1.2.1. Mass Matrix .....................................................................400 12.1.2.2. Skew Symmetry ..............................................................400 12.1.2.3. Boundedness of Dynamic Terms ..................................401 12.1.3. Nonholonomic Robots: Model of Wheel-Set ..............................404 12.2. Trajectory Tracking Control .....................................................................405 12.2.1. Componentwise Control ..............................................................407 12.2.2. Vector Control ................................................................................412 12.2.3. Continuous Feedback/Feedforward Control with Additional Discontinuity Term for Sliding Mode .....................416 12.2.4. Discussion of Sliding Mode Control Design Choices ...............421 12.3. Gradient Tracking Control ........................................................................423 12.3.1. Control Objectives .........................................................................426 12.3.2. Gradient Tracking Control Design for Holonomic Robots ......429 12.3.3. Gradient Tracking Control Design for Nonholonomic Robots ..............................................................................................430 12.4. Application Examples ...............................................................................434 12.4.1. Torque Control for Flexible Robot Joints ....................................434 12.4.2. Collision Avoidance for Mobile Robots in a Known Planar Workspace ..........................................................................438 xii Contents 12.4.3. Collision Avoidance in Higher-Dimensional Known Workspaces .....................................................................................443 12.4.4. Automatic Steering Control for Passenger Cars ........................447 References .............................................................................................................452 Chapter 13 Automotive Applications .........................................................455 13.1. Air/Fuel Ratio Control ..............................................................................455 13.2. Camless Combustion Engine ...................................................................460 13.3. Observer for Automotive Alternator .......................................................468 References ............................................................................................................474 Index ....................................................................................................................477
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spelling	Utkin, Vadim I. Verfasser aut Sliding mode control in electro-mechanical systems Vadim Utkin ; Jürgen Guldner ; Jingxin Shi 2nd ed. Boca Raton [u.a.] CRC Press, Taylor & Francis 2009 XVI, 485 S. graph. Darst. txt rdacontent n rdamedia nc rdacarrier Control theory Electromechanical devices Automatic control Sliding mode control Sliding-Mode (DE-588)4320090-4 gnd rswk-swf Elektromechanisches Bauelement (DE-588)4151849-4 gnd rswk-swf Elektromechanisches Bauelement (DE-588)4151849-4 s Sliding-Mode (DE-588)4320090-4 s DE-604 Guldner, Jürgen Verfasser aut Shi, Jingxin Verfasser aut Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017354010&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Klappentext Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017354010&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Utkin, Vadim I. Guldner, Jürgen Shi, Jingxin Sliding mode control in electro-mechanical systems Control theory Electromechanical devices Automatic control Sliding mode control Sliding-Mode (DE-588)4320090-4 gnd Elektromechanisches Bauelement (DE-588)4151849-4 gnd
subject_GND	(DE-588)4320090-4 (DE-588)4151849-4
title	Sliding mode control in electro-mechanical systems
title_auth	Sliding mode control in electro-mechanical systems
title_exact_search	Sliding mode control in electro-mechanical systems
title_full	Sliding mode control in electro-mechanical systems Vadim Utkin ; Jürgen Guldner ; Jingxin Shi
title_fullStr	Sliding mode control in electro-mechanical systems Vadim Utkin ; Jürgen Guldner ; Jingxin Shi
title_full_unstemmed	Sliding mode control in electro-mechanical systems Vadim Utkin ; Jürgen Guldner ; Jingxin Shi
title_short	Sliding mode control in electro-mechanical systems
title_sort	sliding mode control in electro mechanical systems
topic	Control theory Electromechanical devices Automatic control Sliding mode control Sliding-Mode (DE-588)4320090-4 gnd Elektromechanisches Bauelement (DE-588)4151849-4 gnd
topic_facet	Control theory Electromechanical devices Automatic control Sliding mode control Sliding-Mode Elektromechanisches Bauelement
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017354010&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017354010&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT utkinvadimi slidingmodecontrolinelectromechanicalsystems AT guldnerjurgen slidingmodecontrolinelectromechanicalsystems AT shijingxin slidingmodecontrolinelectromechanicalsystems

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