Linearised Calder\'on problem: Reconstruction and Lipschitz stability for infinite-dimensional spaces of unbounded perturbations

Abstract

We investigate a linearised Calder\'on problem in a two-dimensional bounded simply connected C1,α domain . After extending the linearised problem for L2() perturbations, we orthogonally decompose L2() = k=0∞ Hk and prove Lipschitz stability on each of the infinite-dimensional Hk subspaces. In particular, H0 is the space of square-integrable harmonic perturbations. This appears to be the first Lipschitz stability result for infinite-dimensional spaces of perturbations in the context of the (linearised) Calder\'on problem. Previous optimal estimates with respect to the operator norm of the data map have been of the logarithmic-type in infinite-dimensional settings. The remarkable improvement is enabled by using the Hilbert-Schmidt norm for the Neumann-to-Dirichlet boundary map and its Fr\'echet derivative with respect to the conductivity coefficient. We also derive a direct reconstruction method that inductively yields the orthogonal projections of a general L2() perturbation onto the Hk spaces, hence reconstructing any L2() perturbation.