Modified STDP Triplet Rule Significantly Increases Neuron Training Stability in the Learning of Spatial Patterns

Adv. Artif. Neural Syst. Pub Date : 2016-08-01 DOI:10.1155/2016/1746514

Dalius Krunglevicius

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引用次数: 4

Abstract

Spike-timing-dependent plasticity (STDP) is a set of Hebbian learning rules which are based firmly on biological evidence. STDP learning is capable of detecting spatiotemporal patterns highly obscured by noise. This feature appears attractive from the point of view of machine learning. In this paper three different additive STDP models of spike interactions were compared in respect to training performance when the neuron is exposed to a recurrent spatial pattern injected into Poisson noise. The STDP models compared were all-to-all interaction, nearest-neighbor interaction, and the nearest-neighbor triplet interaction. The parameters of the neuron model and STDP training rules were optimized for a range of spatial patterns of different sizes by the means of heuristic algorithm. The size of the pattern, that is, the number of synapses containing the pattern, was gradually decreased from what amounted to a relatively easy task down to a single synapse. Optimization was performed for each size of the pattern. The parameters were allowed to evolve freely. The triplet rule, in most cases, performed better by far than the other two rules, while the evolutionary algorithm immediately switched the polarity of the triplet update. The all-to-all rule achieved moderate results.

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改进的STDP三联体规则显著提高空间模式学习神经元训练稳定性

spike - time -dependent plasticity (STDP)是一套基于生物学证据的Hebbian学习规则。STDP学习能够检测高度被噪声遮蔽的时空模式。从机器学习的角度来看，这个特征似乎很有吸引力。在本文中，当神经元暴露于注入泊松噪声的反复空间模式时，比较了三种不同的脉冲相互作用的加性STDP模型的训练性能。比较的STDP模型有全对全相互作用、最近邻相互作用和最近邻三重态相互作用。采用启发式算法对神经元模型参数和STDP训练规则进行了优化，以适应不同大小的空间模式。这个模式的大小，也就是包含这个模式的突触的数量，从一个相对容易的任务逐渐减少到一个单一的突触。对每种尺寸的模式都进行了优化。这些参数可以自由变化。在大多数情况下，三元组规则比其他两个规则表现得更好，而进化算法会立即切换三元组更新的极性。全对全规则取得了适度的效果。

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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Adv. Artif. Neural Syst.

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