가야대학교 분성도서관

상단 글로벌/추가 메뉴

회원 로그인


자료검색

자료검색

상세정보

부가기능

Hybrid Feedback Control / [electronic resource]

상세 프로파일

상세정보
자료유형E-Book
개인저자Sanfelice, Ricardo G.
서명/저자사항Hybrid Feedback Control /Ricardo G. Sanfelice.[electronic resource]
발행사항Princeton : Princeton University Press, [2021]
형태사항1 online resource (421 p.).
소장본 주기Added to collection customer.56279.3
ISBN0691189536
9780691189536
내용주기Cover -- Title -- Copyright -- Dedicaiton -- Contents -- Preface -- List of Symbols -- 1 Introduction -- 1.1 Overview -- 1.2 Why Hybrid Control? -- 1.2.1 Hybrid Models Capture Rich Behavior -- 1.2.2 Continuous-Time Systems not Stabilizable via Continuous State-Feedback Can Be Stabilized via Hybrid Control -- 1.2.3 Almost Global Asymptotic Stability Turns Global -- 1.2.4 Nonrobust Stability Becomes Robust -- 1.2.5 Controlled Intersample Behavior and Aperiodic Sampling -- 1.2.6 Hybrid Feedback Control Improves Performance -- 1.3 Exercises -- 1.4 Notes -- 2 Modeling Framework -- 2.1 Overview
2.2 On Truly Hybrid Models -- 2.3 Modeling -- 2.3.1 From Plants and Controllers to Closed-Loop Systems -- 2.3.2 Hybrid Basic Conditions -- 2.3.3 Solution Concept -- 2.3.4 Existence of Solutions to Closed-Loop Systems -- 2.3.5 Hybrid System Models with Disturbances -- 2.4 Numerical Simulation -- 2.5 Exercises -- 2.6 Notes -- 3 Notions and Analysis Tools -- 3.1 Overview -- 3.2 Notions -- 3.2.1 Asymptotic Stability -- 3.2.2 Invariance -- 3.2.3 Robustness to Disturbances -- 3.3 Analysis Tools -- 3.3.1 Hybrid Lyapunov Theorem -- 3.3.2 Hybrid Invariance Principle
3.3.3 Robustness from KL Pre-Asymptotic Stability -- 3.4 Exercises -- 3.5 Notes -- 4 Uniting Control -- 4.1 Overview -- 4.2 Hybrid Controller -- 4.3 Closed-Loop System -- 4.4 Design -- 4.5 Exercises -- 4.6 Notes -- 5 Event-Triggered Control -- 5.1 Overview -- 5.2 Hybrid Controller -- 5.3 Closed-Loop System -- 5.4 Design -- 5.4.1 Completeness of Maximal Solutions -- 5.4.2 Minimum Time in Between Events -- 5.4.3 Pre-Asymptotic Stability -- 5.5 Exercises -- 5.6 Notes -- 6 Throw-Catch Control -- 6.1 Overview -- 6.2 Hybrid Controller -- 6.3 Closed-Loop System -- 6.4 Design
6.4.1 Design of Local Stabilizer k0 -- 6.4.2 Design of Local Stabilizers ki,s and Sets Ai,s -- 6.4.3 Design of Open-Loop Control Laws -- 6.4.4 Design of Bootstrap Controller and Sets -- 6.5 Exercises -- 6.6 Notes -- 7 Synergistic Control -- 7.1 Overview -- 7.2 Hybrid Controller -- 7.3 Closed-Loop System -- 7.4 Design -- 7.4.1 The General Case -- 7.4.2 The Control Affine Case -- 7.5 Exercises -- 7.6 Notes -- 8 Supervisory Control -- 8.1 Overview -- 8.2 Hybrid Controller -- 8.3 Closed-Loop System -- 8.4 Design -- 8.5 Exercises -- 8.6 Notes -- 9 Passivity-Based Control -- 9.1 Overview
9.2 Passivity -- 9.3 Pre-Asymptotic Stability from Passivity -- 9.4 Design -- 9.5 Exercises -- 9.6 Notes -- 10 Feedback Design via Control Lyapunov Functions -- 10.1 Overview -- 10.2 Control Lyapunov Functions -- 10.3 Design -- 10.3.1 Nominal Design -- 10.3.2 Robust Design -- 10.4 Exercises -- 10.5 Notes -- 11 Invariants and Invariance-Based Control -- 11.1 Overview -- 11.2 Nominal and Robust Forward Invariance -- 11.2.1 Forward Invariance -- 11.2.2 Weak Forward Invariance -- 11.2.3 Robust Forward Invariance -- 11.3 Design -- 11.4 Exercises -- 11.5 Notes -- 12 Temporal Logic -- 12.1 Overview
요약A 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.
일반주제명Feedback control systems.
Feedback control systems.
언어영어
기타형태 저록Print version:Sanfelice, Ricardo G.Hybrid Feedback ControlPrinceton : Princeton University Press,c20219780691180229
대출바로가기https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=2503953

소장정보

  • 소장정보

인쇄 인쇄

메세지가 없습니다
No. 등록번호 청구기호 소장처 도서상태 반납예정일 예약 서비스 매체정보
1 WE00020320 629.83 가야대학교/전자책서버(컴퓨터서버)/ 대출가능 인쇄 이미지  

서평

  • 서평

태그

  • 태그

나의 태그

나의 태그 (0)

모든 이용자 태그

모든 이용자 태그 (0) 태그 목록형 보기 태그 구름형 보기
 

퀵메뉴

대출현황/연장
예약현황조회/취소
자료구입신청
상호대차
FAQ
교외접속
사서에게 물어보세요
메뉴추가
quickBottom

카피라이터

  • 개인정보보호방침
  • 이메일무단수집거부

김해캠퍼스 | 621-748 | 경남 김해시 삼계로 208 | TEL:055-330-1033 | FAX:055-330-1032
			Copyright 2012 by kaya university Bunsung library All rights reserved.