Biologically-inspired neuronal adaptation improves learning in neural networks.

Q2 Agricultural and Biological Sciences Communicative and Integrative Biology Pub Date : 2023-01-01 DOI:10.1080/19420889.2022.2163131

Yoshimasa Kubo, Eric Chalmers, Artur Luczak

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引用次数: 2

Abstract

Since humans still outperform artificial neural networks on many tasks, drawing inspiration from the brain may help to improve current machine learning algorithms. Contrastive Hebbian learning (CHL) and equilibrium propagation (EP) are biologically plausible algorithms that update weights using only local information (without explicitly calculating gradients) and still achieve performance comparable to conventional backpropagation. In this study, we augmented CHL and EP with Adjusted Adaptation, inspired by the adaptation effect observed in neurons, in which a neuron's response to a given stimulus is adjusted after a short time. We add this adaptation feature to multilayer perceptrons and convolutional neural networks trained on MNIST and CIFAR-10. Surprisingly, adaptation improved the performance of these networks. We discuss the biological inspiration for this idea and investigate why Neuronal Adaptation could be an important brain mechanism to improve the stability and accuracy of learning.

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受生物启发的神经元适应提高了神经网络的学习能力。

由于人类在许多任务上的表现仍然优于人工神经网络，从大脑中汲取灵感可能有助于改进当前的机器学习算法。对比Hebbian学习(CHL)和平衡传播(EP)是生物学上合理的算法，它们仅使用局部信息(不明确计算梯度)更新权重，并且仍然达到与传统反向传播相当的性能。在本研究中，我们在神经元中观察到的适应效应(神经元对给定刺激的反应在短时间内进行调整)的启发下，增加了CHL和EP。我们将这种自适应特征添加到多层感知器和在MNIST和CIFAR-10上训练的卷积神经网络中。令人惊讶的是，自适应提高了这些网络的性能。我们讨论了这一想法的生物学灵感，并研究了为什么神经元适应可能是提高学习稳定性和准确性的重要大脑机制。

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