一种用于差分运动检测的神经形态集成电路布局

2021 International Conference on Advances in Computing, Communication, and Control (ICAC3) Pub Date : 2021-12-03 DOI:10.1109/icac353642.2021.9697146

Vinay Vishnani, Lance Fernandes, Omkar Deshmukh, Payal Shah, S. S. Rathod

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引用次数: 0

摘要

在许多动物的生物视网膜中都发现了计算微分运动的电路。如果中央和外围视觉感受野的运动(速度)有差异，视网膜上的神经节细胞就会产生一个脉冲，通过轴突传递到大脑。在本文中，我们设计了生物细胞的布局，即光感受器细胞和双极细胞，并将它们进一步结合在一起，形成了一种用于微分运动计算的电路布局。该布局有一个模拟加法器，用于对双极电池的输出响应求和。我们还模拟了单个单元和整个系统的原理图来验证结果，并执行了布局与原理图检查(LVS)。将单个细胞和系统的布局仿真结果与已发表文献中的原理图和生物学实验结果进行了比较。

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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Layout of a Neuromorphic Integrated Circuit for Differential Motion Detection

The circuitry to compute differential motion is found in the biological retina of many animals. If there is a difference between the motion (speed) in the central and peripheral visual receptive field, the ganglion cell in the retina will generate a spike which is relayed via the axon to the brain. In this paper, we have designed layout for biological cells namely - the photoreceptor cell and the bipolar cell, which are further combined together to develop a layout of a circuit for computation of differential motion. The layout has an analog adder which is used to sum the output responses of the bipolar cell. We have also simulated the schematic of individual cells and the entire system to verify the results and performed a layout versus schematic check (LVS). The layout simulation results of individual cells and the system are compared with the results from the schematic and biological experiments which are available in the published literature.

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来源期刊

2021 International Conference on Advances in Computing, Communication, and Control (ICAC3)

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