Overcoming faults using evolution on the PAnDA architecture

2013 IEEE Congress on Evolutionary Computation Pub Date : 2013-06-20 DOI:10.1109/CEC.2013.6557625

Pedro B. Campos, David M. R. Lawson, S. Bale, James Alfred Walker, M. Trefzer, A. Tyrrell

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引用次数: 8

Abstract

This paper explores the potential for transistor level fault tolerance on a new Programmable Analogue and Digital Array (PAnDA) architecture1. In particular, this architecture features Combinatorial Configurable Analogue Blocks (CCABs) that can implement a number of combinatorial functions similar to FPGAs. In addition, PAnDA allows one to reconfigure features of the underlying analogue layer. In PAnDA-EINS, the functions that the CCAB can implement are predefined through the use of a routing block. This paper is a study of whether removing this routing block and allowing direct control of the transistors provides benefits for fault tolerance. Experiments are conducted in two stages. In the first stage, a logic function is evolved on a CCAB and then optimised using a GA. A fault is then injected into the substrate, breaking the logic function. The second stage of the experiment consists of evolving the logic function again on the faulty substrate. The results of these experiments show that the removal of the routing block from the CCAB is beneficial for fault tolerance.

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利用熊猫架构上的进化来克服错误

本文探讨了一种新的可编程模拟和数字阵列(PAnDA)架构上晶体管级容错的潜力1。特别是，该架构具有组合可配置模拟块(CCABs)，可以实现许多类似于fpga的组合功能。此外，PAnDA允许重新配置底层模拟层的特征。在PAnDA-EINS中，CCAB可以实现的功能是通过使用路由块来预定义的。本文研究的是去除该路由块并允许对晶体管进行直接控制是否有利于容错。实验分两个阶段进行。在第一阶段，在CCAB上发展逻辑功能，然后使用遗传算法进行优化。然后将故障注入基片，破坏逻辑功能。实验的第二阶段包括在故障基板上再次进化逻辑功能。实验结果表明，从CCAB中去除路由块有利于容错。

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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2013 IEEE Congress on Evolutionary Computation

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