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利用 PIR 传感器模拟行为作为热感受器:基于尖峰神经元的运动方向分类。

Exploiting the PIR Sensor Analog Behavior as Thermoreceptor: Movement Direction Classification Based on Spiking Neurons.

机构信息

Microelectronic Circuit Design Group, Engineering School, University of Cadiz, Campus Universitario de Puerto Real, Avda. Universidad de Cádiz, nº 10, CP 11519 Puerto Real, Cádiz, Spain.

Applied Robotics Lab, Engineering School, University of Cadiz, Campus Universitario de Puerto Real, Avda. Universidad de Cádiz, nº 10, CP 11519 Puerto Real, Cádiz, Spain.

出版信息

Sensors (Basel). 2023 Jun 22;23(13):5816. doi: 10.3390/s23135816.

DOI:10.3390/s23135816
PMID:37447667
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10346899/
Abstract

Pyroelectric infrared sensors (PIR) are widely used as infrared (IR) detectors due to their basic implementation, low cost, low power, and performance. Combined with a Fresnel lens, they can be used as a binary detector in applications of presence and motion control. Furthermore, due to their features, they can be used in autonomous intelligent devices or included in robotics applications or sensor networks. In this work, two neural processing architectures are presented: (1) an analog processing approach to achieve the behavior of a presynaptic neuron from a PIR sensor. An analog circuit similar to the leaky integrate and fire model is implemented to be able to generate spiking rates proportional to the IR stimuli received at a PIR sensor. (2) An embedded postsynaptic neuron where a spiking neural network matrix together with an algorithm based on digital processing techniques is introduced. This structure allows connecting a set of sensors to the post-synaptic circuit emulating an optic nerve. As a case study, the entire neural processing approach presented in this paper is applied to optical flow detection considering a four-PIR array as input. The results validate both the spiking approach for an analog sensor presented and the ability to retrieve the analog information sent as spike trains in a simulated optic nerve.

摘要

热释电红外传感器(PIR)因其基本实现、低成本、低功耗和性能而被广泛用作红外(IR)探测器。结合菲涅尔透镜,它们可用作存在和运动控制应用中的二进制探测器。此外,由于其特性,它们可用于自主智能设备或包含在机器人应用或传感器网络中。在这项工作中,提出了两种神经处理架构:(1)一种模拟处理方法,用于从 PIR 传感器实现前突触神经元的行为。实现了类似于漏积分和放电模型的模拟电路,以便能够生成与 PIR 传感器接收到的 IR 刺激成正比的尖峰率。(2)一个嵌入式后突触神经元,其中引入了一个尖峰神经网络矩阵以及基于数字处理技术的算法。这种结构允许将一组传感器连接到后突触电路,以模拟视神经。作为案例研究,将本文提出的整个神经处理方法应用于光学流检测,考虑到四-PIR 阵列作为输入。结果验证了所提出的模拟传感器的尖峰方法的有效性,以及以尖峰序列形式检索模拟信息的能力在模拟视神经中发送。

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