进化的尖峰神经网络:一种新的增长算法纠正了老师

J. Schaffer
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引用次数: 10

摘要

脉冲神经网络(snn)由于其计算特性而引起了相当大的兴奋,被认为优于传统的冯·诺伊曼机器,并且与活体大脑共享特性。然而,由于我们缺乏设计方法,构建这些系统的进展受到了限制。我们提出了一种基因驱动的网络增长算法,该算法使遗传算法(进化计算)能够生成和测试snn。该算法的基因组长度增长O(n),其中n是神经元的数量;N也进化了。基因组不仅指定了网络拓扑结构,而且还指定了其所有参数。在实验中,该算法发现snn在给定强音输入的情况下可以有效地产生鲁棒的尖峰爆发行为,这是一种适用于中心模式发生器的应用。即使进化不包括输入尖峰串的扰动,进化的网络对这种扰动表现出显著的鲁棒性。在第二个任务中,序列检测器,发现了几个相关的判别设计,它们都犯了“错误”,因为它们在输入尖峰同时(即不严格按顺序)时触发,但在它们不按顺序时却不会触发。他们也会在距离太近,以至于老师无法宣布他们是按顺序射击的时候开枪。也就是说,进化产生了这些行为,尽管这样做并没有得到明确的奖励。我们乐观地认为,这项技术可能会扩大规模,生产出人类难以生产的强大SNN设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evolving spiking neural networks: A novel growth algorithm corrects the teacher
Spiking neural networks (SNNs) have generated considerable excitement because of their computational properties, believed to be superior to conventional von Neumann machines, and sharing properties with living brains. Yet progress building these systems has been limited because we lack a design methodology. We present a gene-driven network growth algorithm that enables a genetic algorithm (evolutionary computation) to generate and test SNNs. The genome length for this algorithm grows O(n) where n is the number of neurons; n is also evolved. The genome not only specifies the network topology, but all its parameters as well. In experiments, the algorithm discovered SNNs that effectively produce a robust spike bursting behavior given tonic inputs, an application suitable for central pattern generators. Even though evolution did not include perturbations of the input spike trains, the evolved networks showed remarkable robustness to such perturbations. On a second task, a sequence detector, several related discriminating designs were found, all made “errors” in that they fired when input spikes were simultaneous (i.e. not strictly in sequence), but not when they were out of sequence. They also fired when the sequence was too close for the teacher to have declared they were in sequence. That is, evolution produced these behaviors even though it was not explicitly rewarded for doing so. We are optimistic that this technology might be scaled up to produce robust SNN designs that humans would be hard pressed to produce.
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