Spatially lagged predictors from a wider area improve PM2.5 estimation at a finer temporal interval—A case study of Dallas-Fort Worth, United States

Yogita Karale, M. Yuan
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引用次数: 1

Abstract

Fine particulate matter, also known as PM2.5, has many adverse impacts on human health. However, there are few ground monitoring stations measuring PM2.5. Satellite data help fill the gaps in ground measurements, but most studies focus on estimating daily PM2.5 levels. Studies examining the effects of environmental exposome need accurate PM2.5 estimates at fine temporal intervals. This work developed a Convolutional Neural Network (CNN) to estimate the PM2.5 concentration at an hourly average using high-resolution Aerosol Optical Depth (AOD) from the MODIS MAIAC algorithm and meteorological data. Satellite-acquired AOD data are instantaneous measurements, whereas stations on the ground provide an hourly average of PM2.5 concentration. The current work aimed to refine PM2.5 estimates at temporal intervals from 24-h to 1-h averages. Our premise posited the enabling effects of spatial convolution on temporal refinements in PM2.5 estimates. We trained a CNN to estimate PM2.5 corresponding to the hour of AOD acquisition in the Dallas-Fort Worth and surrounding area using 10 years of data from 2006–2015. The CNN accepts images as input. For each PM2.5 station, we strategically subset temporal MODIS images centering at the PM2.5 station. Hence, the resulting image-patch size represented the size of the area around the PM2.5 station. It thus was analogous to spatial lag in spatial statistics. We systematically increased the image-patch size from 3 × 3, 5 × 5, … , to 19 × 19 km2 and observed how increasing the spatial lag impacted PM2.5 estimation. Model performance improved with a larger spatial lag; the model with a 19 × 19 km2 image-patch as input performed best, with a correlation coefficient of 0.87 and a RMSE of 2.57 g/m3 to estimate PM2.5 at in situ stations corresponding to the hour of satellite acquisition time. To overcome the problem of a reduced number of image-patches available for training due to missing AOD, the study employed a data augmentation technique to increase the number of samples available to train the model. In addition to avoiding overfitting, data augmentation also improved model performance.
来自更大区域的空间滞后预测因子在更细的时间间隔上改善了PM2.5的估计——以美国达拉斯-沃斯堡为例
细颗粒物,也被称为PM2.5,对人体健康有许多不利影响。然而,很少有地面监测站测量PM2.5。卫星数据有助于填补地面测量的空白,但大多数研究都集中在估算PM2.5的每日水平上。研究环境暴露的影响需要在很短的时间间隔内准确估计PM2.5。这项工作开发了一个卷积神经网络(CNN),利用MODIS MAIAC算法和气象数据的高分辨率气溶胶光学深度(AOD)来估计PM2.5的每小时平均浓度。卫星获取的AOD数据是瞬时测量数据,而地面站点提供的是PM2.5浓度的每小时平均值。目前的工作旨在从24小时到1小时的平均时间间隔中改进PM2.5的估计。我们的假设假设了空间卷积对PM2.5估算的时间细化的有利影响。我们训练CNN使用2006-2015年10年的数据来估计达拉斯-沃斯堡及周边地区AOD采集时间对应的PM2.5。CNN接受图像作为输入。对于每个PM2.5站点,我们策略性地对以PM2.5站点为中心的时序MODIS图像进行子集化。因此,得到的图像斑块大小代表PM2.5监测站周围区域的大小。因此,它类似于空间统计中的空间滞后。我们系统地将图像斑块大小从3 × 3,5 × 5,…增加到19 × 19 km2,并观察空间滞后的增加如何影响PM2.5的估计。空间滞后越大,模型性能越好;以19 × 19 km2图像块为输入的模型估算PM2.5的相关系数为0.87,RMSE为2.57 g/m3。为了克服由于AOD缺失导致可用于训练的图像补丁数量减少的问题,本研究采用了数据增强技术来增加可用于训练模型的样本数量。除了避免过拟合之外,数据增强还提高了模型的性能。
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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