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

Samar Hosseinzadegan, Andreas Fhager, Mikael Persson, Shireen D. Geimer, Paul M. Meaney

2021IEEE Transactions on Microwave Theory and Techniques26 citationsDOIOpen Access PDF

Abstract

This paper describes a fast microwave tomography reconstruction algorithm based on the two-dimensional discrete dipole approximation. Synthetic data from a finite-element based solver and experimental data from a microwave imaging system are used to reconstruct images and to validate the algorithm. The microwave measurement system consists of 16 monopole antennas immersed in a tank filled with lossy coupling liquid and a vector network analyzer. The low-profile antennas and lossy nature of system make the discrete dipole approximation an ideal forward solver in the image reconstructions. The results show that the algorithm can readily reconstruct a 2D plane of a cylindrical phantom. The proposed forward solver combined with the nodal adjoint method for computing the Jacobian matrix enables the algorithm to reconstruct an image within 6 seconds. This implementation provides a significant time savings and reduced memory requirements and is a dramatic improvement over previous implementations.

Topics & Concepts

Microwave imagingSolverLossy compressionIterative reconstructionComputer scienceImaging phantomAlgorithmMicrowaveComputational scienceOpticsPhysicsComputer visionArtificial intelligenceTelecommunicationsProgramming languageMicrowave Imaging and Scattering AnalysisGeophysical Methods and ApplicationsMicrowave and Dielectric Measurement Techniques
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