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Main Authors: Yuan, Hongpeng, Wang, Ji, Diagne, Mamadou
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2504.01108
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author Yuan, Hongpeng
Wang, Ji
Diagne, Mamadou
author_facet Yuan, Hongpeng
Wang, Ji
Diagne, Mamadou
contents We present an event-triggered boundary control scheme for a class of reaction-diffusion PDEs using operator learning and backstepping method. Our first-of-its-kind contribution aims at learning the backstepping kernels, which inherently induces the learning of the gains in the event trigger and the control law. The kernel functions in constructing the control law are approximated with neural operators (NOs) to improve the computational efficiency. Then, a dynamic event-triggering mechanism is designed, based on the plant and the continuous-in-time control law using kernels given by NOs,to determine the updating times of the actuation signal. In the resulting event-based closed-loop system, a strictly positive lower bound of the minimal dwell time is found, which is independent of initial conditions. As a result, the absence of a Zeno behavior is guaranteed. Besides, exponential convergence to zero of the L_2 norm of the reaction-diffusion PDE state and the dynamic variable in the event-triggering mechanism is proved via Lyapunov analysis. The effectiveness of the proposed method is illustrated by numerical simulation.
format Preprint
id arxiv_https___arxiv_org_abs_2504_01108
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle DeepONet of dynamic event-triggered backstepping boundary control for reaction-diffusion PDEs
Yuan, Hongpeng
Wang, Ji
Diagne, Mamadou
Optimization and Control
We present an event-triggered boundary control scheme for a class of reaction-diffusion PDEs using operator learning and backstepping method. Our first-of-its-kind contribution aims at learning the backstepping kernels, which inherently induces the learning of the gains in the event trigger and the control law. The kernel functions in constructing the control law are approximated with neural operators (NOs) to improve the computational efficiency. Then, a dynamic event-triggering mechanism is designed, based on the plant and the continuous-in-time control law using kernels given by NOs,to determine the updating times of the actuation signal. In the resulting event-based closed-loop system, a strictly positive lower bound of the minimal dwell time is found, which is independent of initial conditions. As a result, the absence of a Zeno behavior is guaranteed. Besides, exponential convergence to zero of the L_2 norm of the reaction-diffusion PDE state and the dynamic variable in the event-triggering mechanism is proved via Lyapunov analysis. The effectiveness of the proposed method is illustrated by numerical simulation.
title DeepONet of dynamic event-triggered backstepping boundary control for reaction-diffusion PDEs
topic Optimization and Control
url https://arxiv.org/abs/2504.01108