Local electrical impedance tomography via projections

TL;DR

This paper presents a novel projection-based method for local electrical impedance tomography that isolates the region of interest by eliminating external conductivity effects, demonstrated with experimental head data.

Contribution

The method introduces a projection technique using the Jacobian's singular vectors to focus on the region of interest, improving local reconstruction accuracy.

Findings

Effective in isolating the region of interest in EIT reconstructions

Demonstrated with experimental data mimicking hemorrhagic stroke growth

Improves local imaging by reducing external conductivity influence

Abstract

This paper introduces a method for approximately eliminating the effect that conductivity changes outside the region of interest have in electrical impedance tomography, allowing to form a local reconstruction in the region of interest only. The method considers the Jacobian matrix of the forward map, i.e., of the map that sends the discretized conductivity to the electrode measurements, at an initial guess for the conductivity. The Jacobian matrix is divided columnwise into two parts: one corresponding to the region of interest and a nuisance Jacobian corresponding to the rest of the domain. The leading idea is to project both the electrode measurements and the forward map onto the orthogonal complement of the span of a number of left-hand singular vectors for a suitably weighted nuisance Jacobian. The weighting can, e.g., account for the element sizes in a finite element discretization or to prior information on the conductivity outside the region of interest. The inverse problem is then solved by considering the projected relation between the measurements and the forward map, only reconstructing the conductivity in the region of interest. The functionality of the method is demonstrated by applying a reconstruction algorithm that combines lagged diffusivity iteration and total variation regularization to experimental data. In particular, data from a head-shaped water tank is considered, with the conductivity change in the region of interest mimicking growth of a hemorrhagic stroke and the changes outside the region of interest imitating physiological variations in the conductivity of the scalp.