在SIMD阵列上实现N*N阶指令的傅里叶变换

Sixth Multidimensional Signal Processing Workshop, Pub Date : 1989-09-06 DOI:10.1109/MDSP.1989.97097

A. Chang, J. Selvage, A. Forman, P. Walker

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引用次数: 0

摘要

只提供摘要形式。在单指令多数据(SIMD)机器上实现了离散傅里叶变换。该实现演示了不适合在顺序机器上使用的算法如何在并行机器上非常有效。SIMD机器是基于几何算术并行处理器(GAPP)的。Bluestein啁啾算法是啁啾- z算法的一种变体，是并行化傅里叶变换的关键。当啁啾- z适应于GAPP阵列的并行结构时，与顺序机器上的O(N*N log N)次运算相比，变换减少到O(N)次运算。用于实现该算法的GAPP阵列为108*384阵列。每个处理元件是一个具有128位RAM的1位串行ALU。每个处理器以网状结构连接到它最近的四个邻居(北、南、东、西)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Implementation of an N*N Fourier transform in order N instructions on a SIMD array

Summary form only given. The discrete Fourier transform has been implemented on a single-instruction, multiple-data (SIMD) machine. The implementation demonstrates how an algorithm that is unsuited for use on a sequential machine can be very effective in a parallel machine. The SIMD machine is based on the Geometric Arithmetic Parallel Processor (GAPP). The Bluestein chirp algorithm, a variation of the chirp-Z algorithm, is the key to parallelizing the Fourier transform. When the chirp-Z is adapted to the parallel architecture of the GAPP array, the transform is reduced to O(N) operations as compared to O(N*N log N) on sequential machines. The GAPP array used to implement this algorithm is a 108*384 array. Each processing element is a one-bit serial ALU with 128 bits of RAM. Each processor is connected to its four nearest neighbors (north, south, east, and west) in a mesh configuration.<>

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Sixth Multidimensional Signal Processing Workshop,

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