地球静止卫星和网格化站点支持下的PM<sub>2.5</sub>精细制图

范东浩; 秦凯; 杜娟; 何秦; 辛世纪; 刘鼎医

doi:10.11834/jrs.20221493

PM2.5遥感估算与制图 | 浏览量 : 0 下载量: 2073 CSCD: 0

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地球静止卫星和网格化站点支持下的PM_2.5精细制图
Fine mapping of PM_2.5 based on measurements from geostationary satellites and grid monitoring stations
2022年26卷第5期页码：1015-1026
收稿：2021-07-19，

纸质出版：2022-05-07
DOI： 10.11834/jrs.20221493
稿件说明：

移动端阅览

范东浩，秦凯，杜娟，何秦，辛世纪，刘鼎医.2022.地球静止卫星和网格化站点支持下的PM_2.5精细制图.遥感学报，26（5）： 1015-1026 DOI： 10.11834/jrs.20221493.

Fan D H，Qin K，Du J，He Q，Xin S J and Liu D Y. 2022. Fine mapping of PM_2.5 based on measurements from geostationary satellites and grid monitoring stations. National Remote Sensing Bulletin， 26（5）：1015-1026 DOI： 10.11834/jrs.20221493.

摘要

许多城市建立的相对稠密的网格化监测站点，为精细化监管城市空气质量奠定了基础。本文选用徐州市网格化监测数据、地球静止卫星Himawari-8/AHI及COMS/GOCI的表观反射率和气溶胶光学厚度数据、气象和其他辅助数据，开展了徐州地区0.005°空间分辨率网格的PM

2.5

浓度精细化制图研究。本文使用了极端梯度提升（XGBoost）、随机森林（RF）及时空加权回归（GTWR）等3种方法，并选用多种特征参数组合进行对比分析。综合分析模型精度和过拟合程度，结果表明XGBoost模型表现最好，其

为0.90，RMSE为11.65 μg/m

。进一步将本文结果与国控站点、清华大学的TAP数据集和马里兰大学的CHAP数据集的对比分析，结果表明基于网格化站点的PM

2.5

制图结果能更好地反映城市内部不同区域的PM

2.5

浓度分布差异性，弥补因国控站点稀疏带来的缺陷，更好地服务于城市空气质量精准管控。

Abstract

The dense gridded air quality monitoring sites established by local governments in China have laid the foundation for fine-tuned monitoring of urban air quality. However

whether it can help improve the capabilities of satellite-based surface PM

2.5

concentration estimation and mapping remain to be tested. To this end

we conducted a case study with Xuzhou as an example.

In order to describe the spatial distribution of PM

2.5

in detail at urban scale

this study used the PM

2.5

concentration data from 172 grid monitoring stations in Xuzhou

the apparent reflectance and aerosol optical thickness data from the Himawari-8/AHI and COMS/GOCI

meteorological data from ERA5 and other auxiliary data to carry out fine mapping study of PM2.5 concentration on the 0.005° spatial resolution grid. The machine learning and geostatistical algorithms of eXtreme Gradient Boosting (XGBoost)

Random Forest (RF) and Geographically and Temporally Weight Regression (GTWR) are applied

and a variety of characteristic parameter combinations (listed in the body of the paper) were selected for comparative analysis.

Compared with other two prediction models

the XGBoost model performed the best

in terms of model accuracy and degree of overfitting

with high correlation coefficient (0.90) and low root mean squard error (11.65 μg/m

). Meanwhile

the best parameter combination includes satellite data from Himawari-8 as well as GOCI and meteorological data from ERA5. These retrieved results were then compared with the measurements obtained from the national grid monitoring stations. For peer comparison

in addition

the TAP (Tracking Air Pollution in China) dataset of Tsinghua University and the CHAP (China High AirPollutants) dataset of the University of Maryland are also involved in this comparison

in the aspect of daily mean value and capacity of fine mapping of PM

2.5

in Xuzhou. Besides

these two datasets use the data from national grid monitoring stations as the validation data..

The following conclusions can be drawn:

(1) Due to its higher temporal resolution

geostationary satellite measurements can better fit hourly urban grid monitoring station data in model prediction

and is more suitable for urban PM

2.5

fine mapping than polar orbit satellite;

(2) The estimation results based on urban grid monitoring stations and satellite measurements can make up for the lack of sparse national control stations to a certain extent

better reflect the difference of PM

2.5

concentration distribution between different regions within a city

and better serve the accurate control of air pollution.

关键词

Keywords

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