Numerical solution of the two-dimensional Calderón problem based on the Hilbert transform of a planar domain

Abstract

Let (M,g) be a C∞ smooth compact connected Riemannian manifold with boundary ∂ M. Consider the Dirichlet problem: Δgu=0,\ u|∂ M=f for f∈ C∞(∂ M). The Dirichlet-to-Neumann (DN) operator Λg:C∞(∂ M) C∞(∂ M) is defined by Λgf=.∂ u∂ν|∂ M, where ν is the unit outer normal to the boundary and u is the unique solution to the Dirichlet problem. Let g∂ be the Riemannian metric on ∂ M induced by g. The Calderón problem is as follows: To what extent is (M,g) determined by the data (∂ M,g∂,Λg)? In the two-dimensional case the surface (M,g) is determined by the DN data uniquely up to conformal equivalence. Knowledge of the DN data is equivalent to knowledge of the Hilbert transform HΩ:C∞(Γ) C∞(Γ) on the boundary curve Γ=∂Ω of a planar domain Ω. We study properties of the Hilbert transform. In particular, we obtain an integral formula for HΩ for a simply connected Ω which generalizes the classical integral formula for the Hilbert transform on the unit circle. This formula is the base of our algorithm for reconstructing a simply connected planar domain from the DN data. Several numerical reconstructions are presented.