制造尖峰神经元的设备物理配方

IF 6.1 Q2 CHEMISTRY, PHYSICAL
Juan Bisquert
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引用次数: 3

摘要

神经元是由生物组织构成的,具有认知特性,可以在各种材料基质中复制。为了创造受大脑启发的计算人工系统,我们可以构建模拟自然系统的微观电子神经元。在本文中,我们讨论了一个尖峰神经元所需的基本材料和器件特性,它可以用阻抗谱和小微扰等效电路元件来表征。我们发现最小的神经元系统需要一个电容器、一个化学电感器和一个负电阻。这些组件可以自然地集成在设备的物理响应中,而不是由单独的电路元件构建。我们确定了光滑振荡的结构条件,这取决于具有内部状态变量的导电系统的某些动力学。这些状态变量可以具有不同的物理性质,例如流体、电子固体或离子有机材料的性质,这意味着功能神经元可以以各种方式构建。我们强调通过阻抗的频谱特征检测Hopf分岔的重要性,Hopf分岔是实现尖峰行为的关键点。为此,我们提供了一种系统的分析方法,可以从阻抗方法中获得临界特征频率。因此,我们提出了一种方法来量化设备的物理和材料特性,以产生特定感觉认知任务所需的神经元的动态特性。通过在电子系统中复制生物神经元的基本特性,有可能创造出具有增强信息处理、模式识别和学习能力的大脑启发计算系统。此外,了解神经元的物理和材料特性有助于我们了解生物神经元如何在复杂的神经网络中发挥作用和相互作用。总的来说,本文提出了一种构建受大脑启发的人工系统的新方法,并提供了对实现电子神经元尖峰行为的重要材料和设备考虑的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Device physics recipe to make spiking neurons
Neurons, which are made of biological tissue, exhibit cognitive properties that can be replicated in various material substrates. To create brain-inspired computational artificial systems, we can construct microscopic electronic neurons that mimic natural systems. In this paper, we discuss the essential material and device properties needed for a spiking neuron, which can be characterized using impedance spectroscopy and small perturbation equivalent circuit elements. We find that the minimal neuron system requires a capacitor, a chemical inductor, and a negative resistance. These components can be integrated naturally in the physical response of the device, instead of built from separate circuit elements. We identify the structural conditions for smooth oscillations that depend on certain dynamics of a conducting system with internal state variables. These state variables can be of diverse physical nature, such as properties of fluids, electronic solids, or ionic organic materials, implying that functional neurons can be built in various ways. We highlight the importance of detecting the Hopf bifurcation, a critical point in achieving spiking behavior, through spectral features of the impedance. To this end, we provide a systematic method of analysis in terms of the critical characteristic frequencies that can be obtained from impedance methods. Thus, we propose a methodology to quantify the physical and material properties of devices to produce the dynamic properties of neurons necessary for specific sensory-cognitive tasks. By replicating the essential properties of biological neurons in electronic systems, it may be possible to create brain-inspired computational systems with enhanced capabilities in information processing, pattern recognition, and learning. Additionally, understanding the physical and material properties of neurons can contribute to our knowledge of how biological neurons function and interact in complex neural networks. Overall, this paper presents a novel approach toward building brain-inspired artificial systems and provides insight into the important material and device considerations for achieving spiking behavior in electronic neurons.
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