Robust Iterative Learning Control of Industrial Batch Systems
Produktdetaljer
Om bidragsyterne
Tao Liu received the Ph.D. degree in Control Science and Engineering from Shanghai Jiao Tong University, Shanghai, China, in 2006. He is a Professor at the Institute of Advanced Control Technology, Dalian University of Technology, Dalian, China. His research interests include industrial process measurement by infrared spectroscopy & imaging, system identification & modeling, control system design, process control, batch process optimization, and data-driven control. He published more than 200 research papers and two monographs. He serves as an associate editor of IEEE Transactions on Industrial Informatics, editorial board member of International Journal of Control, member of the Technical Committee on Chemical Process Control of IFAC, Technical Committee on System Identification and Adaptive Control of the IEEE Control System Society, Technical Committees of Control Theory and Process Control of Chinese Association of Automation. He won the Best Paper Prize of the Journal of Process Control (2020-2022) awarded by International Federation of Automatic Control (IFAC).
Shoulin Hao received his Ph.D degree in Control Theory and Control Engineering from Dalian University of Technology, Dalian, China, in 2018. He is an associate professor with the Institute of Advanced Measurement & Control Technology, Dalian University of Technology, Dalian, China. His research interests include industrial process control, iterative learning control and data-driven control. He published more than 40 research papers and coauthored one monograph.
Youqing Wang received the B.S. degree in Mathematics from Shandong University in 2003, and the Ph.D. degree in Control Science and Engineering from Tsinghua University in 2008. He worked chronologically at Hong Kong University of Science and Technology, China; University of California, Santa Barbara, USA; University of Alberta, Canada; Shandong University of Science and Technology; City University of Hong Kong, China. He is currently a Professor at the Beijing University of Chemical Technology. His research interests include the control performance evaluation theory, the state and fault estimation theory, and the intelligent state monitoring theory. He served as the editor or guest editor of nine international SCI journals and worked part-time in many important international academic organizations, including membership in three technical committees of International Federation of Automatic Control (IFAC) and four professional committees of the Chinese Association of Automation (CAA). He is a recipient of several honors and awards, including IET Fellow, NSFC Distinguished Young Scientists Fund, Journal of Process Control Survey Paper Prize, and ADCHEM2015 Young Author Prize. He is also the first Chinese scholar to win the "Journal of Process Control Best Paper Prize" awarded by IFAC.
Dewei Li received the B.S. degree and the Ph.D. degree in Automation from Shanghai Jiao Tong University, Shanghai, China, in 1993 and 2009, respectively. He worked as a Postdoctor Researcher with Shanghai Jiaotong University from 2009 to 2010. Now he is a Professor at the Department of Automation at Shanghai Jiao Tong University. He is also an Associate Editor of the IFAC journal, Control Engineering Practice. His research interests focus on complex system optimization control, industrial intelligent systems, and intelligent robots. He has published over 300 academic papers in international journals, such as Automatica, IEEE Transactions on Automatic Control, IEEE Transactions on Industrial Electronics, etc. He won the First Prize of Natural Science of the Chinese Association of Automation in 2016, the Second Prize of Chinese Natural Science Award in 2017, and the First Prize of Shanghai Science and Technology Progress in 2023.
This book offers advanced iterative learning control (ILC) and optimization methods for industrial batch systems, facilitating engineering applications subject to time- and batch-varying process uncertainties that could not be effectively addressed by the existing ILC methods. In particular, advanced ILC designs based on the classical proportional-integral-derivative (PID) control loop are presented for the convenience of application, which could not only realize perfect tracking of the desired output trajectory under repetitive process uncertainties and disturbance, but also maintain robust tracking against time-varying uncertainties and disturbance. Moreover, optimization-based ILC designs are provided to deal with the input and/or output constraints of batch process operation, based on the mode predictive control (MPC) principle for process optimization. Furthermore, predictor-based ILC designs are given to deal with time delay in the process input, state or output as often encountered in practice, which could obtain evidently improved control performance compared to the developed ILC methods mainly devoted to delay-free batch processes. In addition, data-driven ILC methods are also presented for application to batch operation systems with unknown dynamics and time-varying uncertainties. Benchmark examples from the existing literature are used to demonstrate the advantages of the proposed ILC methods, along with real applications to industrial injection molding machines, 6-degree-of-freedom robotic manipulator, and refrigerated/heating circulators of pharmaceutical crystallizers. This book will be a valuable source of information for control engineers and researchers in industrial process control theory and engineering field. It can also be used as an advanced textbook for undergraduate and graduate students in control engineering, process system engineering, chemical engineering, mechanical engineering, electrical engineering, biomedical engineering and industrial automation engineering.
This book offers advanced iterative learning control (ILC) and optimization methods for industrial batch systems, facilitating engineering applications subject to time- and batch-varying process uncertainties that could not be effectively addressed by the existing ILC methods.
Preface.- Abbreviations and Symbols.- Chapter 1:Introduction.- Chapter 2:Proportional-Integral (PI) based Iterative Learning Control.- Chapter 3:Proportional-Integral-Derivative (PID) based Iterative Learning Control.- Chapter 4:Closed-Loop ILC Scheme with State Feedback.- Chapter 5:Closed-Loop ILC Scheme with Output Feedback.- Chapter 6:Extended State Observer (ESO) based ILC Design under Process Uncertainties and Disturbance.- Chapter 7:Robust ILC Design under Process Input Constraints.- Chapter 8:2D State Predictor based ILC Design under Input Delay.- Chapter 9:Predictive State Observer (PSO) based ILC Design under Output Delay.- Chapter 10:Robust ILC Design under Process State Delay.- Chapter 11:Robust Data-Driven ILC Design for Unknown System Dynamics.
This book offers advanced iterative learning control (ILC) and optimization methods for industrial batch systems, facilitating engineering applications subject to time- and batch-varying process uncertainties that could not be effectively addressed by the existing ILC methods. In particular, advanced ILC designs based on the classical proportional-integral-derivative (PID) control loop are presented for the convenience of application, which could not only realize perfect tracking of the desired output trajectory under repetitive process uncertainties and disturbance, but also maintain robust tracking against time-varying uncertainties and disturbance. Moreover, optimization-based ILC designs are provided to deal with the input and/or output constraints of batch process operation, based on the mode predictive control (MPC) principle for process optimization. Furthermore, predictor-based ILC designs are given to deal with time delay in the process input, state or output as often encountered in practice, which could obtain evidently improved control performance compared to the developed ILC methods mainly devoted to delay-free batch processes. In addition, data-driven ILC methods are also presented for application to batch operation systems with unknown dynamics and time-varying uncertainties. Benchmark examples from the existing literature are used to demonstrate the advantages of the proposed ILC methods, along with real applications to industrial injection molding machines, 6-degree-of-freedom robotic manipulator, and refrigerated/heating circulators of pharmaceutical crystallizers. This book will be a valuable source of information for control engineers and researchers in industrial process control theory and engineering field. It can also be used as an advanced textbook for undergraduate and graduate students in control engineering, process system engineering, chemical engineering, mechanical engineering, electrical engineering, biomedical engineering and industrial automation engineering.
Produktdetaljer
Om bidragsyterne
Tao Liu received the Ph.D. degree in Control Science and Engineering from Shanghai Jiao Tong University, Shanghai, China, in 2006. He is a Professor at the Institute of Advanced Control Technology, Dalian University of Technology, Dalian, China. His research interests include industrial process measurement by infrared spectroscopy & imaging, system identification & modeling, control system design, process control, batch process optimization, and data-driven control. He published more than 200 research papers and two monographs. He serves as an associate editor of IEEE Transactions on Industrial Informatics, editorial board member of International Journal of Control, member of the Technical Committee on Chemical Process Control of IFAC, Technical Committee on System Identification and Adaptive Control of the IEEE Control System Society, Technical Committees of Control Theory and Process Control of Chinese Association of Automation. He won the Best Paper Prize of the Journal of Process Control (2020-2022) awarded by International Federation of Automatic Control (IFAC).
Shoulin Hao received his Ph.D degree in Control Theory and Control Engineering from Dalian University of Technology, Dalian, China, in 2018. He is an associate professor with the Institute of Advanced Measurement & Control Technology, Dalian University of Technology, Dalian, China. His research interests include industrial process control, iterative learning control and data-driven control. He published more than 40 research papers and coauthored one monograph.
Youqing Wang received the B.S. degree in Mathematics from Shandong University in 2003, and the Ph.D. degree in Control Science and Engineering from Tsinghua University in 2008. He worked chronologically at Hong Kong University of Science and Technology, China; University of California, Santa Barbara, USA; University of Alberta, Canada; Shandong University of Science and Technology; City University of Hong Kong, China. He is currently a Professor at the Beijing University of Chemical Technology. His research interests include the control performance evaluation theory, the state and fault estimation theory, and the intelligent state monitoring theory. He served as the editor or guest editor of nine international SCI journals and worked part-time in many important international academic organizations, including membership in three technical committees of International Federation of Automatic Control (IFAC) and four professional committees of the Chinese Association of Automation (CAA). He is a recipient of several honors and awards, including IET Fellow, NSFC Distinguished Young Scientists Fund, Journal of Process Control Survey Paper Prize, and ADCHEM2015 Young Author Prize. He is also the first Chinese scholar to win the "Journal of Process Control Best Paper Prize" awarded by IFAC.
Dewei Li received the B.S. degree and the Ph.D. degree in Automation from Shanghai Jiao Tong University, Shanghai, China, in 1993 and 2009, respectively. He worked as a Postdoctor Researcher with Shanghai Jiaotong University from 2009 to 2010. Now he is a Professor at the Department of Automation at Shanghai Jiao Tong University. He is also an Associate Editor of the IFAC journal, Control Engineering Practice. His research interests focus on complex system optimization control, industrial intelligent systems, and intelligent robots. He has published over 300 academic papers in international journals, such as Automatica, IEEE Transactions on Automatic Control, IEEE Transactions on Industrial Electronics, etc. He won the First Prize of Natural Science of the Chinese Association of Automation in 2016, the Second Prize of Chinese Natural Science Award in 2017, and the First Prize of Shanghai Science and Technology Progress in 2023.