Neurons as autonomous agents: A biologically inspired framework for cognitive architectures in artificial intelligence

IF 2.1 3区心理学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Cognitive Systems Research Pub Date : 2025-02-24 DOI:10.1016/j.cogsys.2025.101338

Artur Luczak

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引用次数: 0

Abstract

Despite impressive recent advances in artificial intelligence (AI), current deep neural networks still lack the adaptability and energy efficiency inherent to biological systems. Here we suggest that this problem may be overcome by taking inspiration from the brain where neurons operate as autonomous agents, each capable of adjusting its synaptic connections and internal states based on local information. Currently, typical artificial neurons are static nodes, which is in striking contrast to the rich, dynamic computations performed by biological neurons. In this review, we propose redesigning artificial neurons as self-regulating, agent-like units, making actions to maximize future energy/reward. Similarly, as single-celled organisms which can autonomously navigate in complex environments in search for food, neurons can also be viewed as autonomous decision-makers, seeking to maximize their own energy resources. Thus, neurons could be operating similarly like reinforcement learning (RL) agents, which make actions to obtain maximum future reward. Here first we review literature illustrating that biological neurons perform complex computations and employ local, predictive learning rules to anticipate future activity to maximize metabolic energy. Next, we provide examples of recent biologically inspired learning algorithms where artificial neurons are empowered with computational flexibility, similarly to autonomous agents. Networks with neurons using such local learning rules can in some examples outperform current AI algorithms. We also discuss how this can improve scalability of current multi-agent systems (MAS) and energy efficiency. Therefore, designing neurons as autonomous agents may provide an important step toward building human-like cognition.

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神经元作为自主代理：人工智能中认知架构的生物学启发框架

尽管人工智能（AI）最近取得了令人印象深刻的进展，但目前的深度神经网络仍然缺乏生物系统固有的适应性和能量效率。在这里，我们建议通过从大脑中获得灵感来克服这个问题，在大脑中，神经元作为自主代理运行，每个神经元都能够根据局部信息调整其突触连接和内部状态。目前，典型的人工神经元是静态节点，这与生物神经元进行的丰富、动态计算形成鲜明对比。在这篇综述中，我们建议将人工神经元重新设计为自我调节的智能体单元，使未来的能量/奖励最大化。同样，作为能够在复杂环境中自主导航寻找食物的单细胞生物，神经元也可以被视为自主的决策者，寻求最大限度地利用自己的能量资源。因此，神经元可以像强化学习（RL）代理一样运作，它们做出行动以获得最大的未来奖励。在这里，我们首先回顾文献，说明生物神经元执行复杂的计算，并采用局部预测学习规则来预测未来的活动，以最大化代谢能量。接下来，我们提供了最近受生物学启发的学习算法的例子，其中人工神经元被赋予了计算灵活性，类似于自主代理。使用这种局部学习规则的神经元网络在某些情况下可以胜过当前的人工智能算法。我们还讨论了如何提高当前多智能体系统（MAS）的可伸缩性和能源效率。因此，将神经元设计为自主代理可能是构建类人认知的重要一步。

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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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.