Is backpropagation biologically plausible?

International 1989 Joint Conference on Neural Networks Pub Date : 1900-01-01 DOI:10.1109/IJCNN.1989.118705

D. Stork, Jordan Hall

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引用次数: 86

Abstract

The author searches for neurobiologically plausible implementations of the backpropagation gradient descent algorithm. Any such implementation must be consistent with physical constraints such as locality (i.e., that the behavior of any component can be influenced solely by components in physical contact with it) and contingent facts of biology, and must also preserve global network properties such as fault tolerance, stability, and graceful degradation to hardware errors. The authors finds that in several posited implementations these design considerations imply that a finely structured neural connectivity is needed as well as a number of neurons and synapses beyond those inferred from the algorithmic network presentations of backpropagation. Gating synapses (Sigma-Pi units) are present while Hebbian (or pseudo-Hebbian) synapses are absent from all his posited implementations. Although backpropagation can in principle be implemented in neurobiology, such high network structure and the organizational principles required for its generation at the level of individual neurons will require more support from experimental neurobiology.<>

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反向传播在生物学上可信吗?

作者寻找神经生物学上可信的反向传播梯度下降算法的实现。任何这样的实现都必须符合物理约束，如局部性(即，任何组件的行为都可能仅受与其物理接触的组件的影响)和生物学的偶然事实，并且还必须保持全局网络属性，如容错、稳定性和对硬件错误的优雅降级。作者发现，在几个假设的实现中，这些设计考虑意味着需要一个精细结构的神经连接，以及一些神经元和突触，而不是从反向传播的算法网络中推断出来的。门控突触(Sigma-Pi单位)存在，而Hebbian(或伪Hebbian)突触在他所有假设的实现中都不存在。虽然反向传播原则上可以在神经生物学中实现，但这种高网络结构和在单个神经元水平上生成所需的组织原则将需要实验神经生物学的更多支持。

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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International 1989 Joint Conference on Neural Networks

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