生物化学传感、雷达和快速HDL中使用脉冲神经网络的认知处理的新一代进展

Proceedings of the IEEE 2009 National Aerospace & Electronics Conference (NAECON) Pub Date : 2009-07-21 DOI:10.1109/NAECON.2009.5426668

H. Abdel-Aty-Zohdy, Jacob N. Allen

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引用次数: 1

摘要

本文介绍了一种新的脉冲神经网络方法，并将其应用于气味学习、医学和雷达探测等领域。快速HDL是作为15分钟快速原型方法引入的，其中实时实现将在fpga上进行演示。峰值时间依赖的可塑性可以支持基于时空峰值模式的编码方案。尖峰(或脉冲)神经网络(snn)是明确考虑输入时序的模型。网络输入和输出通常表示为一系列尖峰(delta函数或更复杂的形状)。可塑性snn具有能够循环处理信息的优势。峰值时间依赖的可塑性可以通过选择性地加强传递精确时间峰值的突触连接来增强信号的传递，而牺牲那些传递不准确时间峰值的突触。

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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Next-generation advances in cognitive processing using spiking neural networks for biochemical sensing, radar and rapid HDL

This invited plenary paper introduces a novel spiking neural network methodology, and applies it to an odorant learning, medical and radar detection applications. Rapid HDL is introduced as a 15 minute rapid prototyping approach, where real-time implementations will be demoed on FPGAs. The spike-time dependent plasticity can support coding schemes that are based on spatio-temporal spike patterns. Spiking (or pulsed) neural networks (SNNs) are models which explicitly take into account the timing of inputs. The network input and output are usually represented as series of spikes (delta function or more complex shapes). Plasticity SNNs have an advantage of being able to recurrently process information. Spike-time dependent plasticity can enhance signal transmission by selectively strengthening synaptic connections that transmit precisely timed spikes at the expense of those synapses that transmit poorly timed spikes.

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Proceedings of the IEEE 2009 National Aerospace & Electronics Conference (NAECON)

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