Video surveillance at an industrial environment using an address event vision sensor: Comparative between two different video sensor based on a bioinspired retina

Proceedings of the International Conference on Signal Processing and Multimedia Applications Pub Date : 2011-07-18 DOI:10.5220/0003521701310134

F. Perez-Peña, Arturo Morgado Estévez, R. Montero-Gonzalez, A. Linares-Barranco, G. Jiménez-Moreno

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引用次数: 2

Abstract

Nowadays we live in very industrialization world that turns worried about surveillance and with lots of occupational hazards. The aim of this paper is to supply a surveillance video system to use at ultra fast industrial environments. We present an exhaustive timing analysis and comparative between two different Address Event Representation (AER) retinas, one with 64×64 pixel and the other one with 128×128 pixel in order to know the limits of them. Both are spike based image sensors that mimic the human retina and designed and manufactured by Delbruck's lab. Two different scenarios are presented in order to achieve the maximum frequency of light changes for a pixel sensor and the maximum frequency of requested pixel addresses on the AER output. Results obtained are 100 Hz and 1.88 MHz at each case for the 64×64 retina and peaks of 1.3 KHz and 8.33 MHz for the 128×128 retina. We have tested the upper spin limit of an ultra fast industrial machine and found it to be approximately 6000 rpm for the first retina and no limit achieve at top rpm for the second retina. It has been tested that in cases with high light contrast no AER data is lost.

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在工业环境中使用地址事件视觉传感器的视频监控:基于生物视网膜的两种不同视频传感器的比较

如今，我们生活在一个高度工业化的世界，人们开始担心监控和许多职业危害。本文的目的是提供一种用于超快工业环境的监控视频系统。我们对两种不同的地址事件表示(AER)视网膜进行了详尽的时序分析和比较，一种是64×64像素，另一种是128×128像素，以了解它们的局限性。都是基于飙升的图像传感器,模拟人类视网膜和德尔布吕克的实验室设计和制造。为了实现像素传感器的最大光变化频率和AER输出上请求的像素地址的最大频率，提出了两种不同的方案。在每种情况下，64×64视网膜的峰值为100 Hz和1.88 MHz, 128×128视网膜的峰值为1.3 KHz和8.33 MHz。我们测试了一台超高速工业机器的转速上限，发现第一视网膜的转速上限约为6000转，第二视网膜的转速上限没有限制。经测试，在高光对比度的情况下，没有AER数据丢失。

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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Proceedings of the International Conference on Signal Processing and Multimedia Applications

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