Expansion of the Nodal-Adjoint Method for Simple and Efficient Computation of the 2D Tomographic Imaging Jacobian Matrix

Overview

Journal Sensors (Basel)

Publisher MDPI

Specialty Biotechnology

Date 2021 Jan 27

PMID 33499014

Citations 2

Authors

Samar Hosseinzadegan

Andreas Fhager

Mikael Persson

Shireen Geimer

Paul Meaney

Affiliations

Soon will be listed here.

Abstract

This paper focuses on the construction of the Jacobian matrix required in tomographic reconstruction algorithms. In microwave tomography, computing the forward solutions during the iterative reconstruction process impacts the accuracy and computational efficiency. Towards this end, we have applied the discrete dipole approximation for the forward solutions with significant time savings. However, while we have discovered that the imaging problem configuration can dramatically impact the computation time required for the forward solver, it can be equally beneficial in constructing the Jacobian matrix calculated in iterative image reconstruction algorithms. Key to this implementation, we propose to use the same simulation grid for both the forward and imaging domain discretizations for the discrete dipole approximation solutions and report in detail the theoretical aspects for this localization. In this way, the computational cost of the nodal adjoint method decreases by several orders of magnitude. Our investigations show that this expansion is a significant enhancement compared to previous implementations and results in a rapid calculation of the Jacobian matrix with a high level of accuracy. The discrete dipole approximation and the newly efficient Jacobian matrices are effectively implemented to produce quantitative images of the simplified breast phantom from the microwave imaging system.

Citing Articles

Impact of Skin on Microwave Tomography in the Lossy Coupling Medium.

Meaney P, Geimer S, Golnabi A, Paulsen K Sensors (Basel). 2022; 22(19).

PMID: 36236453 PMC: 9572048. DOI: 10.3390/s22197353.

Discrete Dipole Approximation-Based Microwave Tomography for Fast Breast Cancer Imaging.

Hosseinzadegan S, Fhager A, Persson M, Geimer S, Meaney P IEEE Trans Microw Theory Tech. 2021; 69(5):2741-2752.

PMID: 34176958 PMC: 8224266. DOI: 10.1109/tmtt.2021.3060597.

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