Title :
Three-dimensional automatic mesh generation for hybrid electromagnetic simulations
Author :
Wang, Shumin ; Duyn, Jeff H.
Author_Institution :
Lab. of Functional & Mol. Imaging, Nat. Inst. of Neurological Disorders & Stroke, Bethesda, MD, USA
fDate :
4/1/2009 12:00:00 AM
Abstract :
Hybrid mesh generation is required for finite-difference time-domain/finite-element time-domain (FDTD/FETD) hybrid simulations. A combined approach is presented to automatically generate Cartesian/tetrahedral hybrid meshes for open and closed structures. This approach first generates a buffer zone that surrounds a target with specified tightness. The advancing-front technique with ldquosweep-and-retryrdquo is subsequently applied to generate an initial tetrahedral mesh that fills the buffer zone. Finally, the tetrahedral mesh undergoes a combined quality improvement procedure. Due to the low profile of the resulting tetrahedral mesh, the sparse Cholesky decomposition can be applied effectively to solve the resulting FETD matrix. Several examples are provided to demonstrate the main features and the performance of the proposed automatic mesh-generation method.
Keywords :
computational electromagnetics; electromagnetic waves; finite difference time-domain analysis; mesh generation; Cartesian-tetrahedral hybrid mesh; automatic mesh-generation method; finite-difference time-domain hybrid simulation; finite-element time-domain simulation; hybrid electromagnetic simulation; sparse Cholesky decomposition; three-dimensional automatic mesh generation; Computational efficiency; Finite difference methods; Finite element methods; Hybrid power systems; Laboratories; Matrix decomposition; Mesh generation; Molecular imaging; Sparse matrices; Time domain analysis; FDTD methods; Mesh generation; finite difference methods; finite element methods; head; magnetic resonance imaging; matrix inversion; radar cross sections; time-domain analysis;
Journal_Title :
Antennas and Propagation Magazine, IEEE
DOI :
10.1109/MAP.2009.5162020
