模拟VLSI实现的一个海马体脑区非线性系统模型

Proceedings of the Third IEEE International Workshop on Cellular Neural Networks and their Applications (CNNA-94) Pub Date : 1994-12-18 DOI:10.1109/CNNA.1994.381708

T. Berger, B. Sheu, R. Tsai

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引用次数: 3

摘要

海马体是参与学习和记忆功能的主要大脑系统，由具有强烈非线性特性的多个神经元群组成，这些神经元群在局部和非局部相互连接。已经开发了一种模拟VLSI设计，允许不同类别的非线性特定于每个神经元群体来定义在硬件中实现的神经元网络的传递函数。CNN设计的原理已被用于产生相邻处理元素之间的局部交互。非局部交互将在未来的设计中通过使用多个芯片来实现。通过这种方式，我们正试图更好地将真实生物神经元的独特信息处理和学习能力整合到硬件设备中。

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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Analog VLSI implementation of a nonlinear systems model of the hippocampal brain region

The hippocampus is a major brain system involved in learning and memory functions, and consists of multiple populations of neurons with strongly nonlinear properties that are interconnected both locally and non-locally. An analog VLSI design has been developed that allows different classes of nonlinearities specific to each neuron population to define the transfer function of a network of neurons implemented in hardware. Principles of a CNN design have been used to generate local interactions between adjacent processing elements. Non-local interactions will be implemented in future designs with the use of multiple chips. In this manner, we are attempting to better integrate into a hardware device the unique information processing and learning capabilities of real biological neurons known to perform those functions.<>

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Proceedings of the Third IEEE International Workshop on Cellular Neural Networks and their Applications (CNNA-94)

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