空气颗粒物传感中的深度学习:综述

IF 1.1 Q3 PHYSICS, MULTIDISCIPLINARY Journal of Physics Communications Pub Date : 2022-12-01 DOI:10.1088/2399-6528/aca45e
J. Grant-Jacob, B. Mills
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引用次数: 1

摘要

空气中的颗粒物污染是一个全球性的健康问题,影响着所有人口结构的人。为了减少这种污染的影响,并使缓解和政策规划成为可能,量化个人暴露在污染中的程度是必要的。为此,需要通过监测污染热点和污染源,对空气中的颗粒物进行有效监测。此外,由于污染是一个全球性问题,从城市地区到市中心,从工业设施到家庭内部,都各不相同,因此可能需要各种传感器。目前的传感技术要么缺乏世界范围内的物种分辨率,要么缺乏实时能力,要么过于昂贵或过于庞大,无法大规模部署。然而,最近使用深度学习技术的工作扩展了电流传感器的能力,并允许开发具有全球特定物种实时监测潜力的新技术。在此,提出了深度学习如何能够实现传感器设计,以开发用于实时监测颗粒物污染的小型、低成本传感器,同时为个人和整个环境释放预测未来颗粒物事件和从颗粒物推断健康的能力。
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Deep learning in airborne particulate matter sensing: a review
Airborne particulate matter pollution is a global health problem that affects people from all demographics. To reduce the impact of such pollution and enable mitigation and policy planning, quantifying individuals’ exposure to pollution is necessary. To achieve this, effective monitoring of airborne particulates is required, through monitoring of pollution hotspots and sources. Furthermore, since pollution is a global problem, which varies from urban areas to city centres, industrial facilities to inside homes, a variety of sensors might be needed. Current sensing techniques either lack species resolution on a world scale, lack real-time capabilities, or are too expensive or too large for mass deployment. However, recent work using deep learning techniques has expanded the capability of current sensors and allowed the development of new techniques that have the potential for worldwide, species specific, real-time monitoring. Here, it is proposed how deep learning can enable sensor design for the development of small, low-cost sensors for real-time monitoring of particulate matter pollution, whilst unlocking the capability for predicting future particulate events and health inference from particulates, for both individuals and the environment in general.
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来源期刊
Journal of Physics Communications
Journal of Physics Communications PHYSICS, MULTIDISCIPLINARY-
CiteScore
2.60
自引率
0.00%
发文量
114
审稿时长
10 weeks
期刊最新文献
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