递归网络的瞬态混沌维数展开

Christian Keup, Tobias Kühn, David Dahmen, M. Helias
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引用次数: 14

摘要

皮质神经元与脉冲通信,脉冲是时间上的离散事件。即使单个事件的时间是强烈混沌的(微观混沌),事件的速率可能仍然是非混沌的,或者处于所谓的速率混沌的边缘。这种混沌边缘动力学有利于提高神经网络的计算能力。通过发展和应用神经元网络的模型无关场理论,我们分析了异步二元神经元密集连接网络中的两种类型的混沌动力学。我们发现一个强烈依赖于尺寸的过渡到微观混沌。然后,我们揭示了速率混沌定义的核心概念上的困难,确定了两个合理的定义,并表明对于这两个定义,二元网络动力学都没有跨越到速率混沌的过渡。混沌网络中发散轨迹的分析也允许我们在储层计算方法中研究线性不可分刺激类别的分类。我们发现微观混沌迅速扩展了表征的维度,而关键的是,被噪声破坏的维度数量滞后。这意味着即使在混沌状态下,网络的分类性能也会出现一个短暂的峰值,挑战了计算性能在混沌边缘总是最优的观点。这是高维混沌系统中的一般效应,而不是特定于二元网络:我们还在连续“速率”网络、尖峰LIF网络和LSTM网络中证明了这一点。对于二进制和LIF网络,分类性能在每个参与神经元的一次激活内迅速达到峰值,这表明生物神经系统可以利用快速的基于事件的计算,为此我们提出了可测试的预测。
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Transient Chaotic Dimensionality Expansion by Recurrent Networks
Cortical neurons communicate with spikes, which are discrete events in time. Even if the timings of the individual events are strongly chaotic (microscopic chaos), the rate of events might still be non-chaotic or at the edge of what is known as rate chaos. Such edge-of-chaos dynamics are beneficial to the computational power of neuronal networks. We analyze both types of chaotic dynamics in densely connected networks of asynchronous binary neurons, by developing and applying a model-independent field theory for neuronal networks. We find a strongly size-dependent transition to microscopic chaos. We then expose the conceptual difficulty at the heart of the definition of rate chaos, identify two reasonable definitions, and show that for neither of them the binary network dynamics crosses a transition to rate chaos. The analysis of diverging trajectories in chaotic networks also allows us to study classification of linearly non-separable classes of stimuli in a reservoir computing approach. We show that microscopic chaos rapidly expands the dimensionality of the representation while, crucially, the number of dimensions corrupted by noise lags behind. This translates to a transient peak in the networks' classification performance even deeply in the chaotic regime, challenging the view that computational performance is always optimal near the edge of chaos. This is a general effect in high dimensional chaotic systems, and not specific to binary networks: We also demonstrate it in a continuous 'rate' network, a spiking LIF network, and an LSTM network. For binary and LIF networks, classification performance peaks rapidly within one activation per participating neuron, demonstrating fast event-based computation that may be exploited by biological neural systems, for which we propose testable predictions.
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