Inverse initial data reconstruction for Maxwell's equations via time-dimensional reduction method
Abstract
We study an inverse problem for the time-dependent Maxwell system in an inhomogeneous and anisotropic medium. The objective is to recover the initial electric field in a bounded domain , using boundary measurements of the electric field and its normal derivative over a finite time interval. Informed by practical constraints, we adopt an under-determined formulation of Maxwell's equations that avoids the need for initial magnetic field data and charge density information. To address this inverse problem, we develop a time-dimension reduction approach by projecting the electric field onto a finite-dimensional Legendre polynomial-exponential basis in time. This reformulates the original space-time problem into a sequence of spatial systems for the projection coefficients. The reconstruction is carried out using the quasi-reversibility method within a minimum-norm framework, which accommodates the inherent non-uniqueness of the under-determined setting. We prove a convergence theorem that ensures the quasi-reversibility solution approximates the true solution as the noise and regularization parameters vanish. Numerical experiments in a fully three-dimensional setting validate the method's performance. The reconstructed initial electric field remains accurate even with noise in the data, demonstrating the robustness and applicability of the proposed approach to realistic inverse electromagnetic problems.
Cite
@article{arxiv.2506.20777,
title = {Inverse initial data reconstruction for Maxwell's equations via time-dimensional reduction method},
author = {Thuy T. Le and Cong B. Van and Trong D. Dang and Loc H. Nguyen},
journal= {arXiv preprint arXiv:2506.20777},
year = {2025}
}