A hybrid approach for integrating micro-satellite images and sensors network-based ground measurements using deep learning for high-resolution prediction of fine particulate matter (PM2.5) over an indian city, lucknow

IF 4.2 2区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES
Vaishali Jain , Avideep Mukherjee , Soumya Banerjee , Sandeep Madhwal , Michael H. Bergin , Prakash Bhave , David Carlson , Ziyang Jiang , Tongshu Zheng , Piyush Rai , Sachchida Nand Tripathi
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引用次数: 0

Abstract

The detrimental impacts of fine particulate matter (PM2.5) on human health, climate, ecosystems, crops, and building materials are well-established. However, there remain unresolved inquiries regarding the precise location of the sources of PM2.5. This study is the first attempt to use a calibrated sensors-based ambient air quality monitoring network (SAAQM network) and regulatory government monitors to train micro-satellite images for high spatial-resolution air pollution field determination of PM2.5 in Lucknow, Uttar Pradesh, India. A hybrid approach is developed to integrate three different datasets that include microsatellite images, PM2.5 ground measurements, and supporting information (meteorological parameters and geographical coordinates), to be fed into a Random Trees-Random Forest- Convolutional Neural Network (RT-RF-CNN) joint model to estimate PM2.5 concentrations at a sub-km level. The RT-RF-CNN joint model can derive PM2.5 concentrations at a spatial resolution of 500 m with statistically significant indicators such as spatial r of 0.9, a low root-mean-square error of 26.9 μg/m3 and a mean absolute error of 17.2 μg/m3. Based on our approach, the PM2.5 prediction maps using micro-satellite images (spatial resolution of 3m/pixel) and RT-RF-CNN joint model were generated for each day throughout the study period (December 2021–December 2022). The inter-grid comparison of these maps revealed the intra-urban local hotspots and coolspots at a fine-granular level seasonally, monthly, and daily. It is observed that the monsoon season has the highest number of coolspots (67%), while winter (0.1%), post-monsoon (0.5%) and summer (11%) have fewer. It is noted that the high temporal-spatial information of PM2.5 estimates from our integrated approach is not achievable by ground-based measurements and other existing satellite-based estimates alone. The findings of this study have potential applications on a diverse array, encompassing near real-time daily PM2.5 predicted maps, specific air pollution hotspot identification, PM2.5 exposure assessment at the neighbourhood level, and integration of remote sensing-based micro-satellite images and ground-based measurements.

Abstract Image

利用深度学习整合微卫星图像和基于传感器网络的地面测量的混合方法,用于高分辨率预测印度城市勒克瑙上空的细颗粒物(PM2.5)
细颗粒物(PM2.5)对人类健康、气候、生态系统、农作物和建筑材料的有害影响已得到公认。然而,关于 PM2.5 来源的精确位置的问题仍未得到解决。本研究首次尝试使用基于传感器的校准环境空气质量监测网络(SAAQM 网络)和政府监管监测仪来训练微卫星图像,从而对印度北方邦勒克瑙的 PM2.5 进行高空间分辨率的空气污染实地测定。开发了一种混合方法来整合三种不同的数据集,包括微卫星图像、PM2.5 地面测量数据和辅助信息(气象参数和地理坐标),并将其输入随机树-随机森林-卷积神经网络(RT-RF-CNN)联合模型,以估算亚公里级的 PM2.5 浓度。RT-RF-CNN 联合模型可推算出 500 米空间分辨率的 PM2.5 浓度,其统计指标显著,如空间 r 为 0.9,均方根误差低至 26.9 μg/m3,平均绝对误差为 17.2 μg/m3。根据我们的方法,利用微卫星图像(空间分辨率为 3 米/像素)和 RT-RF-CNN 联合模型生成了整个研究期间(2021 年 12 月至 2022 年 12 月)每天的 PM2.5 预测图。这些地图的网格间比较显示了城市内细粒度的局部热点和冷点,包括季节性热点和冷点,月度热点和日度热点。据观察,季风季节的冷点数量最多(67%),而冬季(0.1%)、季风后(0.5%)和夏季(11%)的冷点数量较少。值得注意的是,通过我们的综合方法估算出的 PM2.5 的高时间空间信息是地面测量和其他现有卫星估算无法单独实现的。这项研究的结果有可能应用于多种领域,包括近实时的每日 PM2.5 预测图、特定空气污染热点识别、邻里级别的 PM2.5 暴露评估,以及基于遥感的微卫星图像和地面测量的整合。
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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来源期刊
Atmospheric Environment
Atmospheric Environment 环境科学-环境科学
CiteScore
9.40
自引率
8.00%
发文量
458
审稿时长
53 days
期刊介绍: Atmospheric Environment has an open access mirror journal Atmospheric Environment: X, sharing the same aims and scope, editorial team, submission system and rigorous peer review. Atmospheric Environment is the international journal for scientists in different disciplines related to atmospheric composition and its impacts. The journal publishes scientific articles with atmospheric relevance of emissions and depositions of gaseous and particulate compounds, chemical processes and physical effects in the atmosphere, as well as impacts of the changing atmospheric composition on human health, air quality, climate change, and ecosystems.
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