Neurosynaptic Computational Elements for Adaptive Transient Synchrony

Biophysical Accuracy versus Hardware Complexity

Conference paper (2019)

Authors

Amir Zjajo Signal Processing Systems -

Research Group

Signal Processing Systems () (TU Delft)

FPGA Biophysically-accurate models Neuronomorphic computing Neurosynaptic computatioal elements

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http://resolver.tudelft.nl/uuid:82b488d8-8b9d-4058-bbd5-ec73d57672ac

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Published Date

2019

Language

English

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Faculty

Electrical Engineering, Mathematics and Computer Science

Department

Microelectronics

Research Group

Signal Processing Systems

Abstract

In this paper, we examine electro-chemically accurate, multi-compartment, neurosynaptic computational elements, and analyze their complexity, accuracy, and flexibility in signal processing of a time-varying task. We evaluate distributed patterns of simultaneously firing neurons in space and time, and we establish a transient synchrony and homeostatic regulation mechanism upon the underlying synaptic connectivity. With synchronic spiking, we form synchronous groups of neuronal subpopulations, which represent content forming a coherent entity. The neurosynaptic computational elements implemented on Xilinx Virtex 7 XC7VX550 FPGA board illustrate feasibility of the methodology.

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