What question did this study set out to answer?

This research aims to develop a dynamic control strategy for continuous-time Markov Jump Lur'e Systems under parametric uncertainties.

May 20, 2026Open Access

Output‐Feedback H∞ Detector‐Based Control of Continuous‐Time Markov Jump Lur'e Systems With Sector‐Bound Optimization

Key Points

This research aims to develop a dynamic control strategy for continuous-time Markov Jump Lur'e Systems under parametric uncertainties.
Derives synthesis conditions using Finsler's lemma with additional slack variables.
Implements LMI-based algorithms for controller design.
Conducts numerical experiments based on physically motivated models.
Proposed method shows improved performance in dealing with parametric uncertainties compared to conventional techniques.
Numerical experiments confirm the effectiveness of the control strategy across various scenario simulations.

Abstract

ABSTRACT This paper addresses the problem of dynamic output‐feedback detector‐based control for continuous‐time Markov Jump Lur'e Systems with uncertain transition rate matrices. In contrast to conventional approaches, the proposed synthesis conditions are derived using Finsler's lemma, introducing additional slack variables to facilitate the treatment of fixed‐order dynamic output‐feedback controllers, detector‐based control signals, parametric uncertainties affecting the transition rate matrices, and feedback of the nonlinearity value (when available). The design framework is expressed through LMI‐based algorithms, and the effectiveness and advantages of the proposed method are demonstrated via numerical experiments based on physically motivated models.

Output‐Feedback H∞ Detector‐Based Control of Continuous‐Time Markov Jump Lur'e Systems With Sector‐Bound Optimization

Key Points

Abstract

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