Enregistré dans:
Détails bibliographiques
Auteurs principaux: Ouchdiri, Mohamed Amine, Belhadjoudja, Mohamed-Camil, Maghenem, Mohamed, Benjelloun, Saad, Saoud, Adnane
Format: Preprint
Publié: 2026
Sujets:
Accès en ligne:https://arxiv.org/abs/2604.25909
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866911629352894464
author Ouchdiri, Mohamed Amine
Belhadjoudja, Mohamed-Camil
Maghenem, Mohamed
Benjelloun, Saad
Saoud, Adnane
author_facet Ouchdiri, Mohamed Amine
Belhadjoudja, Mohamed-Camil
Maghenem, Mohamed
Benjelloun, Saad
Saoud, Adnane
contents Boundary controllers have been recently proposed in the literature, via modal decomposition, to achieve $H^1$ stabilization of linear parabolic equations in two and three dimensions. In one dimension ($1$-D), $H^1$ exponential stability is known to imply boundedness and asymptotic convergence of the state to zero in the sense of the max norm. However, in two ($2$-D) and three dimensions ($3$-D), this implication does not systematically hold. In this paper, focusing on the full-state feedback case, our objective is to prove that the modal-decomposition based controller in \cite{Munteanu2017IJC} guarantees, not only $H^1$ exponential stability, but also $H^2$ exponential stability. This implies, in particular, boundedness and asymptotic convergence of the state to zero in the sense of the max norm. Our approach consists in rewriting the Laplacian of the state, required in the $H^2$ norm, as a linear combination of the state and its time derivative. The $L^2$ norm of the state being bounded by the $H^1$ norm, we only analyze the $L^2$ norm of the time derivative of the state.
format Preprint
id arxiv_https___arxiv_org_abs_2604_25909
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle $H^2$ Stabilization of the $2$-D and $3$-D Heat Equation via Modal Decomposition
Ouchdiri, Mohamed Amine
Belhadjoudja, Mohamed-Camil
Maghenem, Mohamed
Benjelloun, Saad
Saoud, Adnane
Optimization and Control
Boundary controllers have been recently proposed in the literature, via modal decomposition, to achieve $H^1$ stabilization of linear parabolic equations in two and three dimensions. In one dimension ($1$-D), $H^1$ exponential stability is known to imply boundedness and asymptotic convergence of the state to zero in the sense of the max norm. However, in two ($2$-D) and three dimensions ($3$-D), this implication does not systematically hold. In this paper, focusing on the full-state feedback case, our objective is to prove that the modal-decomposition based controller in \cite{Munteanu2017IJC} guarantees, not only $H^1$ exponential stability, but also $H^2$ exponential stability. This implies, in particular, boundedness and asymptotic convergence of the state to zero in the sense of the max norm. Our approach consists in rewriting the Laplacian of the state, required in the $H^2$ norm, as a linear combination of the state and its time derivative. The $L^2$ norm of the state being bounded by the $H^1$ norm, we only analyze the $L^2$ norm of the time derivative of the state.
title $H^2$ Stabilization of the $2$-D and $3$-D Heat Equation via Modal Decomposition
topic Optimization and Control
url https://arxiv.org/abs/2604.25909