Title :
Three-Dimensional Large-Scale Micromagnetics Simulation Using Fast Fourier Transformation
Author :
Inami, Nobuhide ; Takeichi, Y. ; Mitsumata, Chiharu ; Iwano, K. ; Ishikawa, Takaaki ; Lee, Soo-Jin ; Yanagihara, Hideto ; Kita, Eiji ; Ono, Keishi
Author_Institution :
High Energy Accel. Res. Organ. (KEK), Tsukuba, Japan
Abstract :
We have successfully performed a large-scale micromagnetics simulation for more than 100 million cells with long-range dipolar interaction using the fast Fourier transform method. The recent demand for a coercivity mechanism in permanent magnets requires an extremely large simulation size, requiring a large-scale micromagnetics simulator. We have developed a large-scale micromagnetics simulator in which a magnetostatic energy calculation is implemented using fast Fourier transform. A hybrid parallel algorithm, which is a combination of shared-memory and distributed-memory parallel algorithms, is used to handle large data arrays. The simulation was carried out on a Hitachi SR16000/M1 supercomputer. The hybrid parallel algorithm used to perform large-scale micromagnetics simulations is discussed.
Keywords :
coercive force; fast Fourier transforms; long-range order; magnetostatics; micromagnetics; permanent magnets; Hitachi SR16000/M1 supercomputer; coercivity mechanism; distributed-memory parallel algorithms; fast Fourier transform method; hybrid parallel algorithm; large data arrays; long-range dipolar interaction; magnetostatic energy calculation; permanent magnets; shared-memory parallel algorithms; three-dimensional large-scale micromagnetic simulation; Computational modeling; Demagnetization; Magnetic hysteresis; Mathematical model; Micromagnetics; Perpendicular magnetic anisotropy; Fast Fourier transformation (FFT); Landau-Lifshitz-Gilbert (LLG) equation; micromagnetics simulation; permanent magnet (PM);
Journal_Title :
Magnetics, IEEE Transactions on
DOI :
10.1109/TMAG.2013.2278221
