异突触可塑性在神经网络中的进化学习

IF 4.6 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

iScience Pub Date : 2025-04-03 DOI:10.1016/j.isci.2025.112340

Zedong Bi , Ruiqi Fu , Guozhang Chen , Dongping Yang , Yu Zhou , Liang Tian

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引用次数: 0

摘要

训练生物物理神经元模型可以深入了解大脑回路的组织和解决问题的能力。由于不稳定性和梯度问题，传统的训练方法（如反向传播）面临复杂模型的挑战。我们探索进化算法（EAs）结合异突触可塑性作为一个无梯度的替代方案。我们的EA模型具有不同的神经元信息通路，通过交替门控进行评估，并以多巴胺驱动的可塑性为指导。该模型从多种生物机制中获得灵感，如多巴胺功能、树突脊柱元可塑性、记忆重放和树突邻近区域内的合作突触可塑性。用这个模型训练的神经网络在认知过程中概括了类似大脑的动态。我们的方法在前馈和循环架构中有效地训练了尖峰和模拟神经网络，在MNIST分类和Atari游戏等任务中也取得了与基于梯度的方法相当的性能。总的来说，这项研究扩展了生物物理神经元模型的训练方法，为传统算法提供了一个强大的替代方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Evolutionary learning in neural networks by heterosynaptic plasticity

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Evolutionary learning in neural networks by heterosynaptic plasticity

Training biophysical neuron models provides insights into brain circuits’ organization and problem-solving capabilities. Traditional training methods like backpropagation face challenges with complex models due to instability and gradient issues. We explore evolutionary algorithms (EAs) combined with heterosynaptic plasticity as a gradient-free alternative. Our EA models agents with distinct neuron information routes, evaluated via alternating gating, and guided by dopamine-driven plasticity. This model draws inspiration from various biological mechanisms, such as dopamine function, dendritic spine meta-plasticity, memory replay, and cooperative synaptic plasticity within dendritic neighborhoods. Neural networks trained with this model recapitulate brain-like dynamics during cognition. Our method effectively trains spiking and analog neural networks in both feedforward and recurrent architectures, it also achieves performance in tasks like MNIST classification and Atari games comparable to gradient-based methods. Overall, this research extends training approaches for biophysical neuron models, offering a robust alternative to traditional algorithms.

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来源期刊

iScience Multidisciplinary-Multidisciplinary

CiteScore

7.20

自引率

1.70%

发文量

1972

审稿时长

6 weeks

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