A Fast, Parallelized Computational Approach Based on Sparse LU Factorization, for Predictions of Spatial and Time-Dependent Currents and Voltages in Full-Body Bio-Models
Abstract
Realistic and accurate numerical simulations of electro-stimulation of tissues and full-body biomodels have been developed and implemented. Typically, whole-body systems are very complex and consist of a multitude of tissues, organs, and subcomponents with diverse properties. From an electrical standpoint, these can be characterized in terms of separate conductivities and permitivities. Accuracy demands good spatial resolution; thus, the overall tissue/animal models need to be discretized into a fine-grained mesh. This can lead to a large number of grid points (especially for a three-dimensional entity) and can place prohibitive requirements of memory storage and execution times on computing machines. Here, the authors include a simple yet fast and efficient numerical implementation. It is based on LU decomposition for execution on a cluster of computers running in parallel with distributed storage of the data in a sparse format. In this paper, the details of electrical tissue representation, the fast algorithm, the relevant biomodels, and specific applications to whole animal studies of electro-stimulation are discussed.
Document Details
- Document Type
- Technical Report
- Publication Date
- Aug 01, 2006
- Accession Number
- ADA463532
Entities
People
- Ashutosh Mishra
- C. D. Clark Iii
- Karl H. Schoenbach
- Ravindra P. Joshi