Showing total 18 results

1. Feedback Stabilization of Switched Linear Systems: A Quantization and Triggering Joint Event-Triggered Mechanism.

Author

Wang, Xiaomei and Zhao, Jun

Subjects

*LINEAR systems, *LYAPUNOV functions, *SYMMETRIC matrices, *COMPUTER simulation

Abstract

This paper adopts a quantization-dependent Lyapunov function to study the output feedback stabilization problem of a switched system subject to output event-triggered sampling and quantization. First, a new event-triggered mechanism related to quantization parameters is proposed, which can obtain a trade-off between the event-triggered frequency and quantization density on the premise of ensuring asymptotic stability of the switched system. Moreover, sufficient conditions are obtained to ensure asymptotic stability of the switched system by a quantization-dependent Lyapunov function. Lastly, through a numerical simulation and PWM-driven boost converter system, we demonstrate the availability of the proposed quantization-dependent Lyapunov function and event-triggered mechanism methods based on quantization parameters, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

2. New Gramians for Switched Linear Systems: Reachability, Observability, and Model Reduction.

Author

Pontes Duff, Igor, Grundel, Sara, and Benner, Peter

Subjects

*LINEAR systems, *VECTOR spaces, *OBSERVABILITY (Control theory), *GLOBAL asymptotic stability, *SYMMETRIC matrices

Abstract

In this paper, we propose new algebraic Gramians for continuous-time switched linear systems, which satisfy generalized Lyapunov equations. The main contribution of this paper is twofold. First, we show that the ranges of those Gramians encode the reachability and observability spaces of a switched linear system. As a consequence, a simple Gramian-based criterion for reachability and observability is established. Second, a balancing-based model order reduction technique is proposed and, under some sufficient conditions, stability preservation and an error bound are shown. Finally, the efficiency of the proposed method is illustrated by means of numerical examples. [ABSTRACT FROM AUTHOR]

Published

2020

3. Distributed Filtering for Switched Linear Systems With Sensor Networks in Presence of Packet Dropouts and Quantization.

Author

Zhang, Dan, Xu, Zhenhua, Karimi, Hamid Reza, and Wang, Qing-Guo

Subjects

*SENSOR networks, *ELECTRIC filter design & construction, *LINEAR systems

Abstract

This paper is concerned with the distributed $H_\infty $ filtering problem of discrete-time switched linear systems in sensor networks in face of packet dropouts and quantization. Specifically, due to the packet dropout phenomenon, the filters may lose access to the real-time switching signal of the plant. It is assumed that the maximal packet dropout number of switching signal is bounded. Then, a distributed filtering system is proposed by further considering the quantization effect. Based on the Lyapunov stability theory, a sufficient condition is obtained for the convergence of filtering error dynamics. The filter gain design is transformed into a convex optimization problem. In this paper, a quantitative relation between the switching rule missing rate and filtering performance is established. Furthermore, the upper bound of the switching rule missing rate is also calculated. Finally, the effectiveness of the proposed filter design is validated by a simulation study on the pulse-width-modulation-driven boost converter circuit. The impact of noise covariance, system dynamics, and network connectivity is studied, and some discussions are presented on how these parameters affect the filtering performance. [ABSTRACT FROM PUBLISHER]

Published

2017

4. Homogeneous Rational Lyapunov Functions for Performance Analysis of Switched Systems With Arbitrary Switching and Dwell Time Constraints.

Author

Chesi, Graziano and Colaneri, Patrizio

Subjects

*LYAPUNOV functions, *LINEAR systems, *LINEAR matrix inequalities, *STANDARD deviations, *KRONECKER products

Abstract

This paper addresses the problems of determining the \mathcal H_2 norm and the root mean square (RMS) gain of continuous-time switched linear systems. A novel class of Lyapunov functions is proposed for reaching this goal, called homogeneous rational Lyapunov functions (HRLFs). It is shown that sufficient conditions for establishing upper bounds of the sought performance indexes in the case of arbitrary switching can be given in terms of linear matrix inequality (LMI) feasibility tests by searching for an HRLF of chosen degree. Moreover, it is shown that these conditions are also necessary by searching for an HRLF of degree sufficiently large. It is worth mentioning that necessary and sufficient LMI conditions have not been proposed yet in the literature for the considered problems. Hence, the paper continues by considering the case of switching with dwell time constraints, showing that analogous LMI conditions can be obtained for this case by searching for a family of HRLFs mutually constrained by the dwell time specification. Some numerical examples illustrate the proposed methodology and highlight the advantages with respect to the existing works. [ABSTRACT FROM AUTHOR]

Published

2017

5. Event-Triggered Dynamic Output Feedback Control for Switched Systems With Frequent Asynchronism.

Author

Fei, Zhongyang, Guan, Chaoxu, and Zhao, Xudong

Subjects

*FEEDBACK control systems, *STATE feedback (Feedback control systems), *LINEAR control systems, *CLOSED loop systems, *STABILITY criterion

Abstract

This paper addresses the event-triggered dynamic output feedback control for switched linear systems with frequent asynchronism. Different from existing work, which limits at most once switching during an interevent interval, we adopt the average dwell time approach without limiting the minimum dwell time of each subsystem, and thus frequent switching is allowed to happen in an interevent interval. Since the difficulty in acquiring the full information of system states, the dynamic output feedback controller is taken into account to stabilize the switched system. By employing a controller-mode-dependent Lyapunov functional, stability criterion is proposed for the resulting closed-loop system, based on which the dynamic output feedback controller together with the mode-dependent event-triggered mechanism is codesigned. Besides, the existence of the lower bound on interevent intervals is attentively discussed, which gets rid of the Zeno behavior. Finally, the effectiveness of the proposed method is illustrated by numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2020

6. Dead-Beat Stabilizability of Discrete-Time Switched Linear Systems: Algorithms and Applications.

Author

Fiacchini, Mirko and Millerioux, Gilles

Subjects

*LINEAR systems, *ALGORITHMS, *STABILITY criterion

Abstract

This paper deals with the dead-beat stabilizability of autonomous discrete-time switched linear systems. Based on a constructive necessary and sufficient condition for dead-beat stabilizability, we propose two algorithms. The first one is concerned with the problem of testing dead-beat stabilizability and computing the shorter stabilizing mode sequence, whenever it exists. The other one implements a method to construct a switched system whose shorter dead-beat stabilizing sequence has a prescribed length. Then, we present numerical assessments and possible applications. [ABSTRACT FROM AUTHOR]

Published

2019

7. Characterization and Optimization of l\infty Gains of Linear Switched Systems.

Author

Naghnaeian, Mohammad and Voulgaris, Petros G.

Subjects

*LINEAR systems, *SWITCHING circuits, *MATHEMATICAL optimization, *ROBUST control, *STABILITY (Mechanics), *LINEAR programming

Abstract

In this paper, we consider the l\infty gain characterizations of linear switched systems (LSS) and present various relevant results on their exact computation and optimization. Depending on the role of the switching sequence, we study two broad cases: first, when the switching sequence attempts to maximize, and second, when it attempts to minimize the l\infty gain. The first, named as worst-case throughout the paper, can be related to robustness of the system to uncontrolled switching; the second relates to situations when the switching can be part to the overall decision making. Although, in general, the exact computation of l\infty gains is difficult, we provide specific classes, the input-output switching systems, for which it is shown that linear programming can be used to obtain the worst-case l\infty gain. This is a sufficiently rich class of systems as any stable LSS can be approximated by one. Certain applications to robust control design are provided where we show that a switched compensation independently of the plant has no advantage over a linear time invariant (LTI) compensation, and further, if the plant is strictly causal, even a switched compensation which has a matched switching with the plant does not provide a better performance over an LTI compensation. Also, we present a new necessary and sufficient condition to check the stability of LSS in form of a model matching problem. On the other hand, if one is interested in minimizing the l\infty gain over the switching sequences, we show that, for finite impulse response (FIR) switching systems the minimizing switching sequence can be chosen to be periodic. For input-only or output-only switching an exact, readily computable, characterization of the minimal l\infty gain is provided, and it is shown that the minimizing switching sequence is constant, which, as also shown, is not true for input-output switching. [ABSTRACT FROM AUTHOR]

Published

2016

8. Dwell-Time-Based Standard $H_\infty$ Control of Switched Systems Without Requiring Internal Stability of Subsystems.

Author

Fu, Jun, Ma, Ruicheng, Chai, Tianyou, and Hu, Zhentao

Subjects

*STATE feedback (Feedback control systems), *LYAPUNOV functions, *DISCRETE-time systems, *LINEAR systems

Abstract

This paper investigates standard $H_\infty$ control of switched systems via dwell-time switchings without posing any internal stability requirements on subsystems of the switched systems. First, a sufficient condition is formed by specifying lower and upper bounds of the dwell time, constraining upper bound of derivative of a Lyapunov function of the active subsystem, and forcing the Lyapunov function values of the overall switched system to decrease at switching times to achieve standard $H_\infty$ control of unforced switched linear systems. Then, in the same framework of the dwell time, sufficient conditions are given for that of the corresponding forced switched linear systems by further designing state feedback controllers. Finally, numerical examples are provided to demonstrate the effectiveness of the proposed results. [ABSTRACT FROM AUTHOR]

Published

2019

9. Necessary and Sufficient Condition for Controlled Distinguishability of Continuous-Time Bilinear Systems.

Author

Motchon, Koffi M. D. and Pekpe, Komi M.

Subjects

*DYNAMICAL systems, *LINEAR systems

Abstract

Controlled distinguishability of two dynamical systems is the property of the systems that guarantees the existence of a control input generating different outputs of the systems regardless of their initial state vectors. These inputs are referred in the literature as discerning control inputs. In this paper, a necessary and sufficient condition for controlled distinguishability of continuous-time bilinear systems is established. It generalizes the classic one provided in the literature for the class of linear systems and a method for designing discerning inputs of bilinear systems that stabilize the systems is also proposed. [ABSTRACT FROM AUTHOR]

Published

2019

10. Optimal Linear Quadratic Regulator of Switched Systems.

Author

Wu, Guangyu, Sun, Jian, and Chen, Jie

Subjects

*GOVERNORS (Machinery), *LINEAR systems, *QUADRATIC programming, *HEURISTIC algorithms

Abstract

This paper considers the optimal control problem of linear switched systems with linear quadratic (LQ) cost or multiple LQ cost. By adopting an embedding transformation, the switching design problem is relaxed and transformed into a traditional optimal control problem. The bang–bang-type solutions of the embedded optimal control problems are obtained for both the positive definite LQ cost case and the multiple LQ cost case, which are the optimal solutions to the original problems. The switching sequence of modes and the switching instants can be calculated by solving a closed-form optimal switching condition. The optimal state feedback control law is determined simultaneously. Finally, numerical results are provided to illustrate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

11. Event-Triggered Control of Continuous-Time Switched Linear Systems.

Author

Xiao, Xiaoqing, Zhou, Lei, Ho, Daniel W. C., and Lu, Guoping

Subjects

*LYAPUNOV functions, *FEEDBACK control systems, *TIME delay systems, *LINEAR systems, *LINEAR matrix inequalities

Abstract

In this paper, we consider the event-triggered control problem for continuous-time switched linear systems. It is assumed that only the sampled information of system state and switching signal is available to the controller at each sampling instant. Based on a mode-dependent event-triggered transmission scheme, the closed-loop system is modeled as a switched system with delayed state and augmented switching signal. Then, an exponential stability condition, characterized by the dwell time and average dwell time of the switching signal, is obtained. The condition presents an extension of the multiple Lyapunov functional method based stability analysis for sampled-data control of nonswitched system. Consequently, the design methods for state-feedback controller gains and event-triggered parameters are then formulated by the properly selected quadratic Lyapunov functional. The analysis results are significant and also lead to an important step to study the event-triggered control for switched system. Finally, based on the definition of event-trigger efficiency, the effectiveness and improvement of the proposed approach are illustrated by two numerical examples. [ABSTRACT FROM AUTHOR]

Published

2019

12. Singular Arcs in Optimal Control of Continuous-Time Bimodal Switched Linear Systems.

Author

Hara, Naoyuki and Konishi, Keiji

Subjects

*LINEAR systems, *MATHEMATICAL models, *SYSTEMS theory, *COMPUTER simulation, *APPLIED mathematics

Abstract

This paper considers a singular problem in optimal control of continuous-time bimodal switched linear systems. A relaxed switched system with a continuous-valued switching signal is considered and the representations of singular control and singular arcs are derived. The similarity in the structure between the singular control and a stabilizing switching law is revealed and an approximation of the singular control by a well-defined switching signal is addressed. The results are demonstrated by numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2019

13. Comments on “Observability of Switched Linear Systems: Characterization and Observer Design”.

Author

Tanwani, Aneel, Shim, Hyungbo, and Liberzon, Daniel

Subjects

*OBSERVABILITY (Control theory), *LINEAR systems, *STOCHASTIC convergence, *STATE estimation in electric power systems, *SWITCHING circuits

Abstract

This note points out certain limitations of our results from the paper mentioned in the title, and provides a modified approach to overcome these limitations. Specifically, the observer design addressed in the aforementioned paper is, in general, only applicable to switched linear systems with invertible state reset maps and this note presents a modified algorithm for state estimation that can also handle non-invertible state reset maps. In the process, we also identify some equalities from that paper which may not hold in general for arbitrary state reset maps. [ABSTRACT FROM PUBLISHER]

Published

2015

14. Aggregation Analysis for Competitive Multiagent Systems With Saddle Points via Switching Strategies.

Author

Zhu, Liying and Xiang, Zhengrong

Subjects

*MULTIAGENT systems, *SADDLEPOINT approximations, *LINEAR control systems

Abstract

This paper addresses the aggregation issues of competitive multiagent systems (CMASs) consisting of competitive agents with multimodes and saddle points. In such CMASs, due to existing mutual competitions, every agent is equipped with finite multimodes, and every mode in any agent is described as a second-order linear time-invariant (LTI) control system. When the origin is the same saddle point of all modes of agents, to investigate aggregation of the CMASs with switching strategies, we first use switched LTI systems with saddle points to formulate such CMASs. Then, two new stability concepts, called initial-state-dependent (ISD) stability and initial-state-independent (ISI) stability, are defined for the CMASs. Based on these new stability concepts, a practical criterion of local/global ISI asymptotic aggregation is proposed for the CMASs. A local/global ISD/ISI asymptotical-stabilizing-control observed as distributed controls of multimodes, stabilizing-switching-paths, and a corresponding algorithm are all designed for local/global aggregation of such CMASs with switching delays. Finally, a numerical example illustrates the effectiveness and practicality of our new results. [ABSTRACT FROM AUTHOR]

Published

2018

15. Output Reachable Set Estimation for Switched Linear Systems and Its Application in Safety Verification.

Author

Xiang, Weiming, Tran, Hoang-Dung, and Johnson, Taylor T.

Subjects

*LINEAR systems, *ELLIPSOIDS, *LYAPUNOV functions, *BISIMULATION, *LINEAR matrix inequalities

Abstract

This paper addresses the output reachable set estimation problem for continuous-time switched linear systems consisting of Hurwtiz stable subsystems. Based on a common Lyapunov function approach, the output reachable set is estimated by a union of bounding ellipsoids. Then, multiple Lyapunov functions with time-scheduled structure are employed to estimate the output reachable set for switched systems under dwell-time constraint. Furthermore, the safety verification problem of uncertain switched systems is investigated based on the result of output reachable set estimation. First, a sufficient condition ensuring the existence of an approximate bisimulation relation between two switched linear systems with a prescribed precision is proposed. Then, the safety verification for an uncertain switched system can be performed through an alternative safety verification for a switched system with exact parameters. Numerical examples are provided to illustrate our results. [ABSTRACT FROM AUTHOR]

Published

2017

16. Analyzing the Stability of Switched Systems Using Common Zeroing-Output Systems.

Author

Lee, Ti-Chung, Tan, Ying, and Mareels, Iven

Subjects

*SWITCHED communication networks, *TIME-varying systems, *ROBUST stability analysis, *LINEAR systems, *LYAPUNOV functions

Abstract

This paper introduces the notion of common zeroing-output systems (CZOS) to analyze the stability of switched systems. The concept of CZOS allows one to verify weak zero-state detectability. It characterizes a common behavior of any individual subsystem when the output signal for each subsystem is “approaching” zero. Heuristically speaking, it removes the effect of switching behavior, and thus enables one to analyze stability properties in systems with complex switching signals. With the help of CZOS, the Krasovskii–LaSalle theorem can be extended to switched nonlinear time-varying systems with both arbitrary switching and more general restricted switching cases. For switched nonlinear time-invariant systems, the needed detectability condition is further simplified, leading to several new stability results. Particularly, when a switched linear time-invariant system is considered, it is possible to generate a recursive method, which combines a Krasovskii–LaSalle result and a nested Matrosov result, to find a CZOS if it exists. The power of the proposed CZOS is demonstrated by consensus problems in literature to obtain a stronger convergence result with weaker conditions. [ABSTRACT FROM AUTHOR]

Published

2017

17. Dwell-Time-Based Observer Design for Unknown Input Switched Linear Systems Without Requiring Strong Detectability of Subsystems.

Author

Ma, Ruicheng, Fu, Jun, and Chai, Tianyou

Subjects

*LINEAR systems, *STABILITY theory, *LYAPUNOV stability, *MATHEMATICS, *LINEAR algebra

Abstract

This paper investigates the state observer design of a class of unknown input switched linear systems via mode-dependent dwell time switchings. The distinguishing feature of the proposed method is that strong detectability condition of subsystems of the switched systems is unnecessarily required. First, a time-varying coordinate transformation is introduced to design a suitable reduced-order observer for each subsystem. Then, computable sufficient conditions on the synthesis of the observers are proposed in the framework of a mode-dependent dwell time technique. Since the observer of an individual subsystem cannot be designed due to unavailability of strong detectability condition of the subsystem, the state of the switched system is estimated under the condition of confining the dwell time by a pair of upper and lower bounds, restricting the growth of the Lyapunov function of the active subsystem and forcing “energy” of the overall switched system to decrease at switching instants. Finally, an example is presented to demonstrate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2017

18. On the Stabilizability of Discrete-Time Switched Linear Systems: Novel Conditions and Comparisons.

Author

Fiacchini, Mirko, Girard, Antoine, and Jungers, Marc

Subjects

*LINEAR systems, *SWITCHING theory, *LYAPUNOV functions, *ELLIPSOIDS, *DISCRETE-time systems

Abstract

In this paper we deal with the stabilizability property for discrete-time switched linear systems. A recent necessary and sufficient characterization of stabilizability, based on set theory, is considered as the reference for comparing the computation-oriented sufficient conditions. The classical BMI conditions based on Lyapunov-Metzler inequalities are considered and extended. Novel LMI conditions for stabilizability, derived from the geometric ones, are presented that permit to combine generality with computational affordability. For the different conditions, the geometrical interpretations are provided and the induced stabilizing switching laws are given. The relations and the implications between the stabilizability conditions are analyzed to infer and compare their conservatism and their complexity. [ABSTRACT FROM AUTHOR]

Published

2016