Vector tomography for reconstructing electric fields with non-zero divergence in bounded domains

TL;DR

This paper extends vector tomography techniques to reconstruct electric fields with non-zero divergence, such as those generated by dipole sources, offering a non-invasive alternative to traditional EEG source imaging methods.

Contribution

It introduces a novel application of vector tomography for reconstructing divergent electric fields, including theoretical derivation and numerical validation.

Findings

Electric fields with non-zero divergence can be reconstructed using VT.

Reconstructed electric field patterns match true source locations accurately.

VT provides a non-invasive alternative to EEG source imaging without source modeling.

Abstract

In vector tomography (VT), the aim is to reconstruct an unknown multi-dimensional vector field using line integral data. In the case of a 2-dimensional VT, two types of line integral data are usually required. These data correspond to integration of the parallel and perpendicular projection of the vector field along integration lines. VT methods are non-invasive, non-intrusive and offer more information on the field than classical point measurements; they are typically used to reconstruct divergence-free (or source-free) velocity and flow fields. In this paper, we show that VT can also be used for the reconstruction of fields with non-zero divergence. In particular, we study electric fields generated by dipole sources in bounded domains which arise, for example, in electroencephalography (EEG) source imaging. To the best of our knowledge, VT has not previously been used to reconstruct such fields. We explain in detail the theoretical background, the derivation of the electric field inverse problem and the numerical approximation of the line integrals. We show that fields with non-zero divergence can be reconstructed from the longitudinal measurements with the help of two sparsity constraints that are constructed from the transverse measurements and the vector Laplace operator. As a comparison to EEG source imaging, we note that VT does not require mathematical modelling of the sources. By numerical simulations, we show that the pattern of the electric field can be correctly estimated using VT and the location of the source activity can be determined accurately from the reconstructed magnitudes of the field.