基于自组织轴突生长的步态模式分类记忆电路

Dennis Michaelis, K. Ochs, S. Jenderny
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引用次数: 1

摘要

神经网络的电路实现也应该考虑动态轴突模型,因为这引入了一个额外的动态方面,由于传输延迟取决于轴突长度。在这项工作中,我们推导了一个自组织轴突生长的电路,在此基础上我们设计了一个用于学习和分类步态模式的神经网络。我们利用具有生长概念的轴突模型的波动数字模型来实现这一目标,由此我们可以推导出相应的电路。这里,轴突的生长是基于带有忆阻器的jaaumann结构。仿真结果表明,该网络训练成功后,确实能够识别出正确的步态模式。与典型的神经网络相比,这种训练不是基于突触权重的变化,而是基于自组织的轴突生长和延迟选择。由于额外的自由度,这可以允许更丰富的动态行为建模神经元网络。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Memristive Circuit for Gait Pattern Classification Based on Self-Organized Axon Growth
Circuit implementations of neuronal networks should also consider dynamic axon models, since this introduces an additional dynamic aspect due to the transmission delays depending on the axon length. In this work, we derive an electrical circuit for self-organized axon growth based on which we design a neuronal network for learning and classifying gait patterns. We do so by utilizing a wave digital model of the axon model with growth concept, from which we can deduce the corresponding electrical circuit. Here, the axon growth is based on Jaumann structures with memristors. Emulation results show that after the successful training of the network, it can indeed recognize the correct gait patterns. In contrast to typical neuronal networks, this training is not based on synaptic weight changes but on the self-organized axon growth and hence delay-selection. Due to the additional degree of freedom, this can allow for a richer dynamic behavior of modeled neuronal networks.
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