Boundary Recovery of Anisotropic Electromagnetic Parameters for the Time Harmonic Maxwell's Equations

Abstract

This work concerns inverse boundary value problems for the time-harmonic Maxwell's equations on differential 1-forms. We formulate the boundary value problem on a 3-dimensional compact and simply connected Riemannian manifold M with boundary ∂ M endowed with a Riemannian metric g. Assuming that the electric permittivity and magnetic permeability μ are real-valued anisotropic (i.e (1,1)- tensors), we aim to determine certain metrics induced by these parameters, denoted by and μ at ∂ M. We show that the knowledge of the impedance and admittance maps determines the tangential entries of and μ at ∂ M in their boundary normal coordinates, although the background volume form cannot be determined in such coordinates due to a non-uniqueness occuring from diffeomorphisms that fix the boundary. Then, we prove that in some cases, we can also recover the normal components of μ up to a conformal multiple at ∂ M in boundary normal coordinates for . Last, we build an inductive proof to show that if and μ are determined at ∂ M in boundary normal coordinates for , then the same follows for their normal derivatives of all orders at ∂ M.