Numerical Modeling and High-Speed Parallel Computing: New Perspectives on Tomographic Microwave Imaging for Brain Stroke Detection and Monitoring
Copyright policy )Numerical Modeling and High-Speed Parallel Computing: New Perspectives on Tomographic Microwave Imaging for Brain Stroke Detection and Monitoring
This article deals with microwave tomography for brain stroke imaging using state-of-the-art numerical modeling and massively parallel computing. Iterative microwave tomographic imaging requires the solution of an inverse problem based on a minimization algorithm (e.g., gradient based) with successive solutions of a direct problem such as the accurate modeling of a whole-microwave measurement system. Moreover, a sufficiently high number of unknowns is required to accurately represent the solution. As the system will be used for detecting a brain stroke (ischemic or hemorrhagic) as well as for monitoring during the treatment, the running times for the reconstructions should be reasonable. The method used is based on high-order finite elements, parallel preconditioners from the domain decomposition method and domain-specific language with the opensource FreeFEM-solver.
- French National Centre for Scientific Research France
- University of Paris France
- Centre national de la recherche scientifique France
- University of Strathclyde United Kingdom
- Sorbonne University France
Brain modeling, Electrical engineering. Electronics Nuclear engineering, TK, 610, optical tomography, Antenna measurements, medical image processing, domain-specific language, Tomography, parallel preconditioners, domain decomposition method, whole-microwave measurement system, Boundary conditions, parallel programming, [SPI.ELEC] Engineering Sciences [physics]/Electromagnetism, Finite element analysis, massively parallel computing, hemorrhagic brain stroke detection, iterative microwave tomographic imaging, open source FreeFEM++ solver, high-order finite elements, 600, Computational modeling, gradient based minimization algorithm, numerical modeling, brain stroke imaging, high-speed parallel computing, inverse problem, ischemic brain stroke detection
Brain modeling, Electrical engineering. Electronics Nuclear engineering, TK, 610, optical tomography, Antenna measurements, medical image processing, domain-specific language, Tomography, parallel preconditioners, domain decomposition method, whole-microwave measurement system, Boundary conditions, parallel programming, [SPI.ELEC] Engineering Sciences [physics]/Electromagnetism, Finite element analysis, massively parallel computing, hemorrhagic brain stroke detection, iterative microwave tomographic imaging, open source FreeFEM++ solver, high-order finite elements, 600, Computational modeling, gradient based minimization algorithm, numerical modeling, brain stroke imaging, high-speed parallel computing, inverse problem, ischemic brain stroke detection
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