English

Inverse problems for linear parabolic equations using mixed formulations - Part 1 : Theoretical analysis

Optimization and Control 2024-02-11 v1

Abstract

We introduce in this document a direct method allowing to solve numerically inverse type problems for linear parabolic equations. We consider the reconstruction of the full solution of the parabolic equation posed in Ω×(0,T)\Omega\times (0,T) - Ω\Omega a bounded subset of RN\mathbb{R}^N - from a partial distributed observation. We employ a least-squares technique and minimize the L2L^2-norm of the distance from the observation to any solution. Taking the parabolic equation as the main constraint of the problem, the optimality conditions are reduced to a mixed formulation involving both the state to reconstruct and a Lagrange multiplier. The well-posedness of this mixed formulation - in particular the inf-sup property - is a consequence of classical energy estimates. We then reproduce the arguments to a linear first order system, involving the normal flux, equivalent to the linear parabolic equation. The method, valid in any dimension spatial dimension NN, may also be employed to reconstruct solution for boundary observations. With respect to the hyperbolic situation considered in \cite{NC-AM-InverseProblems} by the first author, the parabolic situation requires - due to regularization properties - the introduction of appropriate weights function so as to make the problem numerically stable.

Keywords

Cite

@article{arxiv.1508.07854,
  title  = {Inverse problems for linear parabolic equations using mixed formulations - Part 1 : Theoretical analysis},
  author = {Arnaud Munch and Diego Souza},
  journal= {arXiv preprint arXiv:1508.07854},
  year   = {2024}
}

Comments

arXiv admin note: text overlap with arXiv:1502.00114, arXiv:1505.02566

R2 v1 2026-06-22T10:45:19.479Z