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Main Authors: Chun, Maria M. F. M., Edwards, Briana L., Bukshtynov, Vladislav
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2211.06227
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author Chun, Maria M. F. M.
Edwards, Briana L.
Bukshtynov, Vladislav
author_facet Chun, Maria M. F. M.
Edwards, Briana L.
Bukshtynov, Vladislav
contents An efficient computational approach for imaging binary-type physical properties suitable for various models in biomedical applications is developed and validated. The proposed methodology includes gradient-based multiscale optimization with multilevel control space reduction based on principal component analysis, optimal switching between the fine and coarse scales, and their effective re-parameterization. The reduced dimensional controls are used interchangeably at both scales to accumulate the optimization progress and mitigate side effects. Computational efficiency and superior quality of obtained results are achieved through proper communication between solutions obtained at the fine and coarse scales. Reduced size of control spaces supplied with adjoint-based gradients facilitates the application of this algorithm to models of high complexity and also to a broad range of problems in biomedical sciences and outside. The performance of the complete computational framework is tested with 2D inverse problems of cancer detection by electrical impedance tomography (EIT) in applications to synthetic models and models based on real breast cancer images. The results demonstrate the superior performance of the new method and its high potential for minimizing possibilities for false positive and false negative screening and improving the overall quality of the EIT-based procedures in medical practice.
format Preprint
id arxiv_https___arxiv_org_abs_2211_06227
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Multiscale Optimization via Enhanced Multilevel PCA-based Control Space Reduction for Electrical Impedance Tomography Imaging
Chun, Maria M. F. M.
Edwards, Briana L.
Bukshtynov, Vladislav
Optimization and Control
An efficient computational approach for imaging binary-type physical properties suitable for various models in biomedical applications is developed and validated. The proposed methodology includes gradient-based multiscale optimization with multilevel control space reduction based on principal component analysis, optimal switching between the fine and coarse scales, and their effective re-parameterization. The reduced dimensional controls are used interchangeably at both scales to accumulate the optimization progress and mitigate side effects. Computational efficiency and superior quality of obtained results are achieved through proper communication between solutions obtained at the fine and coarse scales. Reduced size of control spaces supplied with adjoint-based gradients facilitates the application of this algorithm to models of high complexity and also to a broad range of problems in biomedical sciences and outside. The performance of the complete computational framework is tested with 2D inverse problems of cancer detection by electrical impedance tomography (EIT) in applications to synthetic models and models based on real breast cancer images. The results demonstrate the superior performance of the new method and its high potential for minimizing possibilities for false positive and false negative screening and improving the overall quality of the EIT-based procedures in medical practice.
title Multiscale Optimization via Enhanced Multilevel PCA-based Control Space Reduction for Electrical Impedance Tomography Imaging
topic Optimization and Control
url https://arxiv.org/abs/2211.06227