Title :
Constant geometry fast Fourier transforms on array processors
Author_Institution :
Dept. of Math. Sci., Nevada Univ., Las Vegas, NV, USA
fDate :
3/1/1993 12:00:00 AM
Abstract :
Matrix algebra is used to design and validate parallel algorithms for large constant-geometry fast Fourier transforms (FFTs) on fixed-size array processors. The N-point radix 2 case for a linear array processor with N/2 cells is identical to the usual procedure corresponding to the matrix factorization of M.C. Pease, (1968). The algorithms are engendered by matrix factorizations, which themselves depend on a basic factorization of the perfect shuffle. The resulting data movement is realized in parallel as relatively small perfect shuffles inside each local memory and along each row and column of the array processor, without requiring that the complete array itself have the shuffle-exchange network
Keywords :
fast Fourier transforms; logic arrays; matrix algebra; parallel algorithms; array processors; constant geometry FFT; fast Fourier transforms; local memory; matrix factorization; parallel algorithms; perfect shuffle; Algebra; Algorithm design and analysis; Fast Fourier transforms; Fourier transforms; Geometry; Multiprocessor interconnection networks; Parallel architectures; Pipelines; Prediction algorithms; Very large scale integration;
Journal_Title :
Computers, IEEE Transactions on
