English

Approximation and uniqueness results for the nonlocal diffuse optical tomography problem

Analysis of PDEs 2024-08-01 v2

Abstract

We investigate the inverse problem of recovering the diffusion and absorption coefficients (σ,q)(\sigma,q) in the nonlocal diffuse optical tomography equation (div(σ))su+qu=0 in Ω(-\text{div}( \sigma \nabla))^s u+q u =0 \text{ in }\Omega from the nonlocal Dirichlet-to-Neumann (DN) map Λσ,qs\Lambda^s_{\sigma,q}. The purpose of this article is to establish the following approximation and uniqueness results. - Approximation: We show that solutions to the conductivity equation div(σv)=0 in Ω \text{div}( \sigma \nabla v)=0 \text{ in }\Omega can be approximated in H1(Ω)H^1(\Omega) by solutions to the nonlocal diffuse optical tomography equation and the DN map Λσ\Lambda_\sigma related to conductivity equation can be approximated by the nonlocal DN map Λσ,qs\Lambda_{\sigma,q}^s. - Local uniqueness: We prove that the absorption coefficient qq can be determined in a neighborhood N\mathcal{N} of the boundary Ω\partial\Omega provided σ\sigma is already known in N\mathcal{N}. - Global uniqueness: Under the same assumptions as for the local uniqueness result, and if one of the potentials vanishes in Ω\Omega, then one can turn with the help of \ref{item 1 abstract} the local determination into a global uniqueness result. It is worth mentioning that the approximation result relies on the Caffarelli--Silvestre type extension technique and the geometric form of the Hahn--Banach theorem.

Keywords

Cite

@article{arxiv.2406.06226,
  title  = {Approximation and uniqueness results for the nonlocal diffuse optical tomography problem},
  author = {Yi-Hsuan Lin and Philipp Zimmermann},
  journal= {arXiv preprint arXiv:2406.06226},
  year   = {2024}
}

Comments

37 pages

R2 v1 2026-06-28T16:59:32.068Z