多fpga分区的并行紧凑遗传算法

Proceedings Ninth Euromicro Workshop on Parallel and Distributed Processing Pub Date : 2001-02-07 DOI:10.1109/EMPDP.2001.905033

R. Baraglia, R. Perego, J. Hidalgo, J. Lanchares, F. Tirado

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引用次数: 20

摘要

本文研究了一种紧凑的遗传算法来解决多fpga分区问题。目前，多fpga系统已广泛应用于硬件动态重构、数字电路仿真和数值计算等领域。设计并实现了一种紧凑遗传算法(cGA)的顺序和并行版本。cGA的特性允许节省内存以解决大型多fpga分区问题，同时利用并行性可以减少执行时间。在不同的多fpga分区实例上进行了多次实验，取得了良好的结果，表明该方案是解决多fpga分区问题的可行方案。

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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A parallel compact genetic algorithm for multi-FPGA partitioning

In this paper we investigate the design of a compact genetic algorithm to solve multi-FPGA partitioning problems. Nowadays Multi-FPGA systems are used for a great variety of applications such as dynamically reconfigurable hardware applications, digital circuit emulation, and numerical computation. Both a sequential and a parallel version of a compact genetic algorithm (cGA) have been designed and implemented on a cluster of workstations. The peculiarities of the cGA permits to save memory in order to address large multi-FPGA partitioning problems, while the exploitation of parallelism allows to reduce execution times. The good results achieved on several experiments conducted on different multi-FPGA partitioning instances show that this solution is viable to solve multi-FPGA partitioning problems.

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Proceedings Ninth Euromicro Workshop on Parallel and Distributed Processing

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