04921nam 2200937 450 991055448570332120230629234635.00-691-18953-610.1515/9780691189536(OCoLC)1223098136(CKB)4100000011525489(MiAaPQ)EBC6376042(DE-B1597)566906(DE-B1597)9780691189536(OCoLC)1202473965(EXLCZ)99410000001152548920210406d2021 uy 0engur||#||||||||txtrdacontentcrdamediacrrdacarrierHybrid feedback control /Ricardo G. SanfelicePrinceton, New Jersey ;Oxford :Princeton University Press,[2021]©20211 online resource (424 p.) 78 b/w illus. 1 tablePrinceton series in applied mathematics0-691-18022-9 Frontmatter --Contents --Preface --List Of Symbols --1 Introduction --2 Modeling Framework --3 Notions And Analysis Tools --4 Uniting Control --5 Event-Triggered Control --6 Throw-Catch Control --7 Synergistic Control --8 Supervisory Control --9 Passivity-Based Control --10 Feedback Design Via Control Lyapunov Functions --11 Invariants And Invariance-Based Control --12 Temporal Logic --Appendix A: Mathematical Review --Appendix B: Proof Of The Hybrid Lyapunov Theorem --Bibliography --IndexA comprehensive introduction to hybrid control systems and designHybrid control systems exhibit both discrete changes, or jumps, and continuous changes, or flow. An example of a hybrid control system is the automatic control of the temperature in a room: the temperature changes continuously, but the control algorithm toggles the heater on or off intermittently, triggering a discrete jump within the algorithm. Hybrid control systems feature widely across disciplines, including biology, computer science, and engineering, and examples range from the control of cellular responses to self-driving cars. Although classical control theory provides powerful tools for analyzing systems that exhibit either flow or jumps, it is ill-equipped to handle hybrid control systems.In Hybrid Feedback Control, Ricardo Sanfelice presents a self-contained introduction to hybrid control systems and develops new tools for their analysis and design. Hybrid behavior can occur in one or more subsystems of a feedback system, and Sanfelice offers a unified control theory framework, filling an important gap in the control theory literature. In addition to the theoretical framework, he includes a plethora of examples and exercises, a Matlab toolbox (as well as two open-source versions), and an insightful overview at the beginning of each chapter.Relevant to dynamical systems theory, applied mathematics, and computer science, Hybrid Feedback Control will be useful to students and researchers working on hybrid systems, cyber-physical systems, control, and automation.Princeton series in applied mathematics.Feedback control systemsAn Introduction to Hybrid Dynamical Systems.Arjan J. van der Schaft.Daniel Liberzon.Formal Verification of Control System Software.Hans Schumacher.Impulsive and Hybrid Dynamical Systems.Lyapunov theory.Pierre-Loic Garoche.Switching in Systems and Control.Wassim Haddad.automation.buffer variables.closed-loop system response.continuous-time.control theory.coupling mechanism.cyberphysical systems.discrete time.engineering systems.feedback control design.flashing fireflies.flows and jumps.hybrid behavior.hybrid control strategies.hybrid dynamical system.hybrid systems.interfaces.internet of things.logic-based algorithm.numerical simulation.robotic humanoids.self-driving vehicles.signal conditioners.subsystems.synergistic feedback.systems analysis.the controller.the plant.timer variable.Feedback control systems.629.83Sanfelice Ricardo G.1977-1217464MiAaPQMiAaPQMiAaPQBOOK9910554485703321Hybrid feedback control2815625UNINA