Massive Efficiencies to be Realized through GPU Computations in Finite Element Optimization: The Promises and Observations

被引:0
作者
Hoole, S. Ratnajeevan H. [1 ]
机构
[1] Election Commiss, Sarana Mawatha 10107, Rajagiriya, Sri Lanka
来源
2015 IEEE 10TH INTERNATIONAL CONFERENCE ON INDUSTRIAL AND INFORMATION SYSTEMS (ICIIS) | 2015年
关键词
finite element method (FEM); parallelization; matrix computation; Graphics Processing Unit (GPU); speedup; OPTIMAL-DESIGN; ELECTROMAGNETIC DEVICES; GENETIC ALGORITHM; SHAPE OPTIMIZATION; FEM; MAGNET; FIELDS;
D O I
暂无
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
In finite element optimization, the computational load limits the size of problem that can be solved. Finite element computation involves the solution of large matrix equations. Then optimization requires several such equations to be solved. Parallelization has been the preferred route to overcome this problem but was again limited by the cost of computers and the number of processors available. The graphics processing unit (GPU) on a PC provides a means of implementing the massive computations on numerous parallel threads cheaply on PCs. The purpose of this is to review finite element matrix equation solution on the GPU and point out areas where further investigation is warranted. Our intention is to direct computational research and computer architecture development so that we may use the GPU better for more effective computational parallelization in finite element field computation.
引用
收藏
页码:390 / 394
页数:5
相关论文
共 40 条
[1]   CONCURRENT STRUCTURAL OPTIMIZATION ON MASSIVELY-PARALLEL SUPERCOMPUTER [J].
ADELI, H ;
KUMAR, S .
JOURNAL OF STRUCTURAL ENGINEERING-ASCE, 1995, 121 (11) :1588-1597
[2]   EFFICIENT OPTIMAL DESIGN OF STRUCTURES BY GENERALIZED STEEPEST DESCENT PROGRAMMING [J].
ARORA, JS ;
HAUG, EJ .
INTERNATIONAL JOURNAL FOR NUMERICAL METHODS IN ENGINEERING, 1976, 10 (04) :747-766
[3]  
Attardo E. A., 2012, ANT PROP SOC INT S A
[4]   ELEMENT-BY-ELEMENT VECTOR AND PARALLEL COMPUTATIONS [J].
CAREY, GF ;
BARRAGY, E ;
MCLAY, R ;
SHARMA, M .
COMMUNICATIONS IN APPLIED NUMERICAL METHODS, 1988, 4 (03) :299-307
[5]  
Devon Y., 2011, THESIS
[6]   DESIGN OF SUPERCONDUCTING MHD SADDLE MAGNETS [J].
DRAGO, G ;
MOLFINO, P ;
REPETTO, M ;
SECONDO, G ;
LIA, GMA ;
MONTANARI, I ;
RIBANI, PL .
IEEE TRANSACTIONS ON MAGNETICS, 1992, 28 (01) :450-453
[7]   FINITE ELEMENT MATRIX GENERATION ON A GPU [J].
Dziekonski, A. ;
Sypek, P. ;
Lamecki, A. ;
Mrozowski, M. .
PROGRESS IN ELECTROMAGNETICS RESEARCH-PIER, 2012, 128 :249-265
[8]   Optimal design of linear oscillatory actuator using genetic algorithm [J].
Enomoto, H ;
Harada, K ;
Ishihara, Y ;
Todaka, T ;
Hirata, K .
IEEE TRANSACTIONS ON MAGNETICS, 1998, 34 (05) :3515-3518
[9]   Alternate Parallel Processing Approach for FEM [J].
Fernandez, David M. ;
Dehnavi, Maryam Mehri ;
Gross, Warren J. ;
Giannacopoulos, Dennis .
IEEE TRANSACTIONS ON MAGNETICS, 2012, 48 (02) :399-402
[10]   PERFORMANCE DERIVATIVE CALCULATIONS AND OPTIMIZATION PROCESS [J].
GITOSUSASTRO, S ;
COULOMB, JL ;
SABONNADIERE, JC .
IEEE TRANSACTIONS ON MAGNETICS, 1989, 25 (04) :2834-2839
1234