可编程逻辑阵列结构演化的广义析取分解

First NASA/ESA Conference on Adaptive Hardware and Systems (AHS'06) Pub Date : 2006-06-15 DOI:10.1109/AHS.2006.47

E. Stomeo, T. Kalganova, Cyrille Lambert

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引用次数: 20

摘要

可进化硬件是指一种可自我重构的电子电路，其电路的配置是在进化算法的控制下进行的。当应用于解决现实世界的应用程序时，可演化硬件显示出其主要缺陷之一，即可伸缩性。在过去的几年里，已经提出了几种技术来避免和/或解决这个问题。广义析取分解(GDD)就是其中一种方法。GDD与双向增量进化和(1+lambda)进化策略配合使用，成功地实现了基于FPGA结构的大型组合逻辑电路的进化。本文实现了一种改进的广义析交分解和最近提出的多种群遗传算法，并对其求解基于可编程逻辑阵列(PLA)结构的大型组合逻辑电路的可扩展性进行了测试

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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Generalized Disjunction Decomposition for the Evolution of Programmable Logic Array Structures

Evolvable hardware refers to a self reconfigurable electronic circuit, where the circuit configuration is under the control of an evolutionary algorithm. Evolvable hardware has shown one of its main deficiencies, when applied to solving real world applications, to be scalability. In the past few years several techniques have been proposed to avoid and/or solve this problem. Generalized disjunction decomposition (GDD) is one of these proposed methods. GDD was successful for the evolution of large combinational logic circuits based on a FPGA structure when used together with bi-directional incremental evolution and with (1+lambda) evolution strategy. In this paper a modified generalized disjunction decomposition, together with a recently introduced multi-population genetic algorithm, are implemented and tested for its scalability for solving large combinational logic circuits based on programmable logic array (PLA) structures

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First NASA/ESA Conference on Adaptive Hardware and Systems (AHS'06)

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