Bio-Inspired Mamba: Temporal Locality and Bioplausible Learning in Selective State Space Models

arXiv - CS - Neural and Evolutionary Computing Pub Date : 2024-09-17 DOI:arxiv-2409.11263

Jiahao Qin

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Abstract

This paper introduces Bio-Inspired Mamba (BIM), a novel online learning framework for selective state space models that integrates biological learning principles with the Mamba architecture. BIM combines Real-Time Recurrent Learning (RTRL) with Spike-Timing-Dependent Plasticity (STDP)-like local learning rules, addressing the challenges of temporal locality and biological plausibility in training spiking neural networks. Our approach leverages the inherent connection between backpropagation through time and STDP, offering a computationally efficient alternative that maintains the ability to capture long-range dependencies. We evaluate BIM on language modeling, speech recognition, and biomedical signal analysis tasks, demonstrating competitive performance against traditional methods while adhering to biological learning principles. Results show improved energy efficiency and potential for neuromorphic hardware implementation. BIM not only advances the field of biologically plausible machine learning but also provides insights into the mechanisms of temporal information processing in biological neural networks.

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受生物启发的曼巴：选择性状态空间模型中的时域性和可生物学习

本文介绍了生物启发曼巴（BIM），这是一种用于选择性状态空间模型的新型在线学习框架，它将生物学习原理与曼巴架构融为一体。BIM 将实时循环学习（Real-Time RecurrentLearning，RTRL）与类似于尖峰定时可塑性（Spike-Timing-Dependent Plasticity，STDP）的局部学习规则相结合，解决了尖峰神经网络训练中的时间局部性和生物可信性难题。我们的方法利用了时间反向传播和 STDP 之间的内在联系，提供了一种计算高效的替代方法，同时保持了捕捉长程依赖性的能力。我们在语言建模、语音识别和生物医学信号分析任务中对 BIM 进行了评估，结果表明，在遵循生物学习原理的同时，BIM 的性能与传统方法相比极具竞争力。结果表明，BIM 的能效得到了提高，并有可能实现超形态硬件。BIM 不仅推动了生物可信机器学习领域的发展，还为生物神经网络中的时间信息处理机制提供了新的见解。

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arXiv - CS - Neural and Evolutionary Computing

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