A DOMAIN -DECOMPOSITION BASED PARALLEL PROCEDURE FOR THE COMBINED FINITE-DISCRETE ELEMENT METHOD IN 2D

Although the Combined Finite-Discrete Element Method (FDEM) has proven itself in dealing with problems of complex shapes, fracture and fragmentation, there is a stark reality of CPU requirements when dealing with industrial scale problems; in other words there is a compelling need for a parallel-processing framework to address large scale and grand challenge type of problems. One of the more recent development efforts in the context of FDEM was directed to implement the parallelization techniques needed for this method. In this paper a FDEM parallelization framework has been developed. Static domain decomposition and message passing inter-processor communication have been implemented in the FDEM code. The performance of the FDEM code in three typical problems is presented. For a discrete particle problem over 900 times speed-up has been obtained on 1000 processors. It has also been shown that the performance, especially efficiency of the parallelized software, still depends on the particular architecture of the computer hardware being used. However, the test results clearly demonstrate that it is possible to achieve very high efficiency even when a relatively large number of processors are employed.