TY - GEN
T1 - A parallel high-order fictitious domain approach for biomechanical applications
AU - Ruess, Martin
AU - Varduhn, Vasco
AU - Rank, Ernst
AU - Yosibash, Zohar
PY - 2012/12/13
Y1 - 2012/12/13
N2 - The focus of this contribution is on the parallelization of the Finite Cell Method (FCM) applied for biomechanical simulations of human femur bones. The FCM is a high-order fictitious domain method that combines the simplicity of Cartesian grids with the beneficial properties of hierarchical approximation bases of higher order for an increased accuracy and reliablility of the simulation model. A pre-computation scheme for the numerically expensive parts of the finite cell model is presented that shifts a significant part of the analysis update to a setup phase of the simulation, thus increasing the update rate of linear analyses with time-varying geometry properties to a range that even allows user interactive simulations of high quality. Paralellization of both parts, the pre-computation of the model stiffness and the update phase of the simulation is simplified due to a simple and undeformed cell structure of the computation domain. A shared memory parallelized implementation of the method is presented and its performance is tested for a biomedical application of clinical relevance to demonstrate the applicability of the presented method.
AB - The focus of this contribution is on the parallelization of the Finite Cell Method (FCM) applied for biomechanical simulations of human femur bones. The FCM is a high-order fictitious domain method that combines the simplicity of Cartesian grids with the beneficial properties of hierarchical approximation bases of higher order for an increased accuracy and reliablility of the simulation model. A pre-computation scheme for the numerically expensive parts of the finite cell model is presented that shifts a significant part of the analysis update to a setup phase of the simulation, thus increasing the update rate of linear analyses with time-varying geometry properties to a range that even allows user interactive simulations of high quality. Paralellization of both parts, the pre-computation of the model stiffness and the update phase of the simulation is simplified due to a simple and undeformed cell structure of the computation domain. A shared memory parallelized implementation of the method is presented and its performance is tested for a biomedical application of clinical relevance to demonstrate the applicability of the presented method.
KW - Finite Cell Method
KW - biomechanics
KW - fictitious domain
KW - high-order approximation
KW - pre-integration scheme
KW - shared memory parallelization
UR - http://www.scopus.com/inward/record.url?scp=84870732772&partnerID=8YFLogxK
U2 - 10.1109/ISPDC.2012.45
DO - 10.1109/ISPDC.2012.45
M3 - Conference contribution
AN - SCOPUS:84870732772
SN - 9780769548050
T3 - Proceedings - 2012 11th International Symposium on Parallel and Distributed Computing, ISPDC 2012
SP - 279
EP - 285
BT - Proceedings - 2012 11th International Symposium on Parallel and Distributed Computing, ISPDC 2012
T2 - 2012 11th International Symposium on Parallel and Distributed Computing, ISPDC 2012
Y2 - 25 June 2012 through 29 June 2012
ER -