English

Observability inequalities for heat equations with potentials

Optimization and Control 2025-07-29 v2 Analysis of PDEs

Abstract

This paper is mainly concerned with the observability inequalities for heat equations with time-dependent Lipschtiz potentials. The observability inequality for heat equations asserts that the total energy of a solution is bounded above by the energy localized in a subdomain with an observability constant. For a bounded measurable potential V=V(x,t)V = V(x,t), the factor in the observability constant arising from the Carleman estimate is best known to be exp(CV2/3)\exp(C\|V\|_{\infty}^{2/3}) (even for time-independent potentials). In this paper, we show that, for Lipschtiz potentials, this factor can be replaced by exp(C(V1/2+tV1/3))\exp(C(\|\nabla V\|_{\infty}^{1/2} +\|\partial_tV\|_{\infty}^{1/3} )), which improves the previous bound exp(CV2/3)\exp(C\|V\|_{\infty}^{2/3}) in some typical scenarios. As a consequence, with such a Lipschitz potential, we obtain a quantitative regular control in a null controllability problem. In addition, for the one-dimensional heat equation with some time-independent bounded measurable potential V=V(x)V = V(x), we obtain the optimal observability constant.

Keywords

Cite

@article{arxiv.2409.09476,
  title  = {Observability inequalities for heat equations with potentials},
  author = {Jiuyi Zhu and Jinping Zhuge},
  journal= {arXiv preprint arXiv:2409.09476},
  year   = {2025}
}

Comments

31 pages

R2 v1 2026-06-28T18:44:47.569Z