Gürel, LeventErgül, Özgür2016-02-082016-02-0820130018-9219http://hdl.handle.net/11693/21141Due to its O(N log N) complexity, the multilevel fast multipole algorithm (MLFMA) is one of the most prized algorithms of computational electromagnetics and certain other disciplines. Various implementations of this algorithm have been used for rigorous solutions of large-scale scattering, radiation, and miscellaneous other electromagnetics problems involving 3-D objects with arbitrary geometries. Parallelization of MLFMA is crucial for solving real-life problems discretized with hundreds of millions of unknowns. This paper presents the hierarchical partitioning strategy, which provides a very efficient parallelization of MLFMA on distributed-memory architectures. We discuss the advantages of the hierarchical strategy over previous approaches and demonstrate the improved efficiency on scattering problems discretized with millions of unknowns. © 1963-2012 IEEE.EnglishComputational electromagnetics3D objectArbitrary geometryDistributed MemoryElectromagneticsHierarchical parallelizationHierarchical partitioningLarge-scale scatteringMultilevel fast multipole algorithmsParallelizationsReal-life problemsRigorous solutionScattering problemsSurface integral equationsAlgorithmsComputational electromagneticsArticle10.1109/JPROC.2012.2222331