Eigenstructure of the linearized electrical impedance tomography problem under radial perturbations

Abstract

We analyze the Fr\'echet derivative F, that maps a perturbation in conductivity to the linearized change in boundary measurements governed by the conductivity equation. The domain is taken to be the unit ball B ⊂ Rd with d ≥ 2, and we choose perturbations η from the Hilbert space L2(B). Under the condition that the perturbations are rotationally symmetric, we show that the eigenfunctions of the linear approximation F η correspond to the spherical harmonics. Furthermore, we establish an explicit formula for the associated eigenvalues and show that for perturbations from any bounded subset, the decay of these eigenvalues is uniform with respect to the degree of the spherical harmonics. The established structure of F η enables us to show that the Fr\'echet derivative F can be approximated by finite-rank operators when restricted to rotationally symmetric perturbations. Both the extension to L2(B) perturbations and the approximability by finite-rank operators are favorable properties for further analysis of F in numerical algorithms.

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