Talk at the Flatiron Institute

During my September visit I delivered a scientific talk at the Computational Mathematics Seminar at the Flatiron Institute. My topic was Electrical impedance tomography and virtual X-rays, and you can download my slides here: PDF 53MB.

Abstract: Electrical Impedance Tomography (EIT) is a nonlinear PDE-based imaging modality where a patient is probed with harmless electric currents, and the resulting surface voltages are measured. EIT image reconstruction is an ill-posed inverse problem, meaning very sensitive to noise in the data and modelling errors. However, one can use complex geometric optics (CGO) solutions and a nonlinear Fourier transform to do robust medical imaging; this is the so-called regularized D-bar method. A connection between EIT and X-ray tomography was found in [Greenleaf et al. 2018] using microlocal analysis. Fourier transform applied to the spectral parameter of CGO solutions produces virtual X-ray projections, enabling a novel filtered back-projection type nonlinear reconstruction algorithm for EIT. It is remarkable how this new approach decomposes the EIT image reconstruction process in several steps, where all ill-posedness is confined in two linear steps. Therefore, we can separate the nonlinearity and ill-posedness of the fundamental EIT problem. Furthermore, the new decomposition enables targeted machine learning approaches as only one or two (mathematically well-structured) steps in the imaging chain are solved using neural networks.