千岛湖水体表层温度遥感估算方法对比研究

张琳敏; 梅格致; 刘明亮; 李渊; 施坤; 朱梦圆; 李慧赟; 郭宇龙; 王嘉诚

doi:10.11834/jrs.20232460

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千岛湖水体表层温度遥感估算方法对比研究
Comparison of lake surface water temperature retrieval algorithms： A case study of Lake Qiandaohu
2023年页码：1-20
网络出版日期： 2023-03-14 ，
DOI： 10.11834/jrs.20232460

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张琳敏，梅格致，刘明亮，李渊，施坤，朱梦圆，李慧赟，郭宇龙，王嘉诚.XXXX.千岛湖水体表层温度遥感估算方法对比研究.遥感学报，XX（XX）： 1-20

ZHANG Linmin，MEI Gezhi，LIU Mingliang，LI Yuan，SHI Kun，ZHU Mengyuan，LI Huiyun，GUO Yulong，Wang Jiacheng. XXXX. Comparison of lake surface water temperature retrieval algorithms： A case study of Lake Qiandaohu. National Remote Sensing Bulletin， XX（XX）：1-20
张琳敏，梅格致，刘明亮，李渊，施坤，朱梦圆，李慧赟，郭宇龙，王嘉诚.XXXX.千岛湖水体表层温度遥感估算方法对比研究.遥感学报，XX（XX）： 1-20 DOI： 10.11834/jrs.20232460.

ZHANG Linmin，MEI Gezhi，LIU Mingliang，LI Yuan，SHI Kun，ZHU Mengyuan，LI Huiyun，GUO Yulong，Wang Jiacheng. XXXX. Comparison of lake surface water temperature retrieval algorithms： A case study of Lake Qiandaohu. National Remote Sensing Bulletin， XX（XX）：1-20 DOI： 10.11834/jrs.20232460.

摘要

湖泊水体表层温度是气候和环境变化的重要指示因子，遥感技术是水体表层温度监测的重要手段。温度反演算法在不同湖库水体的适用性各异，针对清洁型深水湖库的水体表层温度反演算法适用性仍有待进一步研究。本研究以千岛湖为研究区，利用Landsat 8卫星数据，对比了基于辐射传输方程的算法（RTE）、单窗算法（MWA）、普适性单通道算法（GSCA）、实用单通道算法（PSCA）、劈窗算法（SWA_D和SWA_G）和Landsat 8 Collection 2 Level-2（C2L2）温度产品的精度，探究了各算法中相关参数的适用性和敏感性，刻画了千岛湖2013-2021年水体表层温度时空分布特征。研究结果表明：（1）针对Landsat 8数据的第10和11波段，千岛湖最适宜的水体比辐射率分别为0.9926和0.9877；（2）整体上，劈窗算法的精度优于单通道算法，Landsat温度产品的估算精度适中。其中，劈窗算法SWA_G精度最优，平均相对误差（MAPE）为7.61%，均方根误差（RMSE）为2.0 ℃；（3）千岛湖水体表层温度具有显著的时空分异特征。季节上，千岛湖水体表层温度冬季最低（14.2 ± 0.6 ℃），夏季最高（31.0 ± 0.5 ℃）。空间上，西北库区（23.0 ± 0.3 ℃）和西南库区（22.8 ± 0.2 ℃）水体表层温度最高，东北库区（22.2 ± 0.3 ℃）水体表层温度最低。本研究验证了不同温度反演算法在清洁型深水湖库的适用性，为清洁型深水湖库水体表层温度反演提供了经验借鉴。

Abstract

Objective Lake surface water temperature is an important indicator of water quality

lake physical environment and climate change. Monitoring lake surface water temperature and understanding its spatiotemporal variations are critical for local government to protect lake ecosystem. Remote sensing is an effective method to monitor lake surface water temperature

and many algorithms were developed and applied to retrieve lake surface water temperature. However

the suitability of these algorithms is varied in different lakes. Especially

the suitability of these algorithms in deep

oligotrophic-to-mesotrophic lakes still needs to be discussed. Thus

taking Lake Qiandaohu

China as the study area

we are trying to validate the performance of various land surface temperature retrieval algorithms

analyze the sensitivity of the parameters in each algorithm and mapping the spatiotemporal distribution of lake surface water temperature.Method In this study

six land surface temperature retrieval algorithms (Radiative Transfer Equation algorithm

Mono-window algorithm

Generalized Single-Channel algorithm

Practical Single-Channel algorithm and two Split-Window algorithms) were selected to retrieve lake surface water temperature using Landsat 8 data in Lake Qiandaohu. The performance of these algorithms and the Landsat 8 Collection 2 Level-2 (C2L2) temperature product were validated with in-situ buoy data. By applying the best performed algorithm to 37 cloud-free Landsat 8 data collected from 2013 to 2021

the spatial and temporal distribution of lake surface water temperature in Lake Qiandaohu were mapped. Furthermore

the sensitivity of the relevant parameters (water surface emissivity

effective mean atmospheric temperature

atmospheric water vapor content

up-welling radiance

down-welling radiance and atmospheric transmittance) in each algorithm were explored.Result The results showed that: (1) for the band 10 and band 11 of Landsat 8 data

the most suitable water surface emissivity in Lake Qiandaohu is 0.9926 and 0.9877

respectively; (2) the accuracy of the Split-Window algorithm is better than that of the Single-Channel algorithm

and the estimation accuracy of Landsat temperature product is moderate. The Split-Window Algorithm

SWA_G

shows the best performance

with the mean absolute percentage error (MAPE) of 7.61% and the root mean square error (RMSE) of 2.0 ℃. The MPAE and RMSE value of the Landsat 8 C2L2 temperature product are 9.33% and 2.08 ℃

respectively; (3) lake surface water temperature in Lake Qiandaohu has significant spatial and temporal variation. Seasonally

the lake surface water temperature of Lake Qiandaohu has the lowest value (14.2 ± 0.6 ℃) and highest value (31.0 ± 0.5 ℃) in winter and summer

respectively. Spatially

the lake surface water temperature was higher in the northwest segment (23.0 ± 0.3 ℃) and southwest segment (22.8 ± 0.2 ℃) and lower in the northeast segment (22.2 ± 0.3 ℃); (4) The Radiative Transfer Equation algorithm is sensitive to the up-welling radiance and atmospheric transmittance. The Mono-window algorithm shows less sensitivity to the effective mean atmospheric temperature and atmospheric transmittance.Conclusion In conclusion

in Lake Qiandaohu

the Split-Window algorithm has the best performance and the least dependency with atmospheric parameters. On the other hand

the Single-Channel algorithm is suit for retrieval long-term lake surface water temperature utilizing Landsat series data. Our study validated the performance of various land surface temperature retrieval algorithms in deep

oligotrophic-to-mesotrophic lake and provided a reference for the remotely estimating lake surface water temperature in other similar lakes.

关键词

水温Landsat千岛湖水体比辐射率敏感性分析

Keywords

lake surface water temperatureLandsatLake Qiandaohuwater surface emissivitysensitivity analysis

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