Hebbian spatial encoder with adaptive sparse connectivity

IF 2.1 3区心理学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Cognitive Systems Research Pub Date : 2024-08-22 DOI:10.1016/j.cogsys.2024.101277

Petr Kuderov , Evgenii Dzhivelikian , Aleksandr I. Panov

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Abstract

Biologically plausible neural networks have demonstrated efficiency in learning and recognizing patterns in data. This paper proposes a general online unsupervised algorithm for spatial data encoding using fast Hebbian learning. Inspired by the Hierarchical Temporal Memory (HTM) framework, we introduce the SpatialEncoder algorithm, which learns the spatial specialization of neurons’ receptive fields through Hebbian plasticity and k-WTA (k winners take all) inhibition. A key component of our model is a two-part synaptogenesis algorithm that enables the network to maintain a sparse connection matrix while adapting to non-stationary input data distributions. In the MNIST digit classification task, our model outperforms the HTM SpatialPooler in terms of classification accuracy and encoding stability. Compared to another baseline, a two-layer artificial neural network (ANN), our model achieves competitive classification accuracy with fewer iterations required for convergence. The proposed model offers a promising direction for future research on sparse neural networks with adaptive neural connectivity.

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具有自适应稀疏连接性的海比空间编码器

仿生神经网络在学习和识别数据中的模式方面表现出了高效性。本文提出了一种利用快速希比安学习进行空间数据编码的通用在线无监督算法。受分层时态记忆（HTM）框架的启发，我们引入了空间编码器算法（SpatialEncoder algorithm），该算法通过希比可塑性和 k-WTA（k 胜者全取）抑制来学习神经元感受野的空间特化。我们模型的一个关键组成部分是一种由两部分组成的突触生成算法，它能使网络在适应非稳态输入数据分布的同时保持稀疏的连接矩阵。在 MNIST 数字分类任务中，我们的模型在分类准确性和编码稳定性方面都优于 HTM SpatialPooler。与另一个基准--双层人工神经网络（ANN）相比，我们的模型以更少的收敛迭代次数达到了具有竞争力的分类准确性。所提出的模型为未来研究具有自适应神经连接的稀疏神经网络提供了一个很有前景的方向。

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来源期刊

Cognitive Systems Research 工程技术-计算机：人工智能

CiteScore

9.40

自引率

5.10%

发文量

审稿时长

>12 weeks

期刊介绍： Cognitive Systems Research is dedicated to the study of human-level cognition. As such, it welcomes papers which advance the understanding, design and applications of cognitive and intelligent systems, both natural and artificial. The journal brings together a broad community studying cognition in its many facets in vivo and in silico, across the developmental spectrum, focusing on individual capacities or on entire architectures. It aims to foster debate and integrate ideas, concepts, constructs, theories, models and techniques from across different disciplines and different perspectives on human-level cognition. The scope of interest includes the study of cognitive capacities and architectures - both brain-inspired and non-brain-inspired - and the application of cognitive systems to real-world problems as far as it offers insights relevant for the understanding of cognition. Cognitive Systems Research therefore welcomes mature and cutting-edge research approaching cognition from a systems-oriented perspective, both theoretical and empirically-informed, in the form of original manuscripts, short communications, opinion articles, systematic reviews, and topical survey articles from the fields of Cognitive Science (including Philosophy of Cognitive Science), Artificial Intelligence/Computer Science, Cognitive Robotics, Developmental Science, Psychology, and Neuroscience and Neuromorphic Engineering. Empirical studies will be considered if they are supplemented by theoretical analyses and contributions to theory development and/or computational modelling studies.