Combing remote sensing information entropy and machine learning for ecological environment assessment of Hefei-Nanjing-Hangzhou region, China

Combing remote sensing information entropy and machine learning for ecological environment assessment of Hefei-Nanjing-Hangzhou region, China

Urban ecological environment is the basis of citizens’ survival and development. A rapid and objective urban ecological environment assessment (UEEA) plays an important role in the urban sustainable development and environment protection. This study established an improved urban ecological comfort i...

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Veröffentlicht in:Journal of environmental management 2023-01, Vol.325 (Pt B), p.116533, Article 116533
Hauptverfasser: Zhang, Hongyi, Liu, Yong, Li, Xinghua, Feng, Ruitao, Gong, Yuting, Jiang, Yazhen, Guan, Xiaobin, Li, Shuang
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Sprache:eng
Schlagworte:
aerosols
algorithms
autumn
China
Cities
Entropy
Entropy method
environmental assessment
Environmental Monitoring - methods
environmental protection
heat
Machine Learning
normalized difference vegetation index
Random forest
Remote sensing
Remote Sensing Technology
Reproducibility of Results
spring
summer
surface temperature
sustainable development
time series analysis
turbidity
UECIIMP
Urban ecological environment assessment (UEEA)
urbanization
winter
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container_end_page
container_issue Pt B
container_start_page 116533
container_title Journal of environmental management
container_volume 325
creator Zhang, Hongyi
Liu, Yong
Li, Xinghua
Feng, Ruitao
Gong, Yuting
Jiang, Yazhen
Guan, Xiaobin
Li, Shuang
description Urban ecological environment is the basis of citizens’ survival and development. A rapid and objective urban ecological environment assessment (UEEA) plays an important role in the urban sustainable development and environment protection. This study established an improved urban ecological comfort index (UECIIMP), which is based on our previous UECI and fully composed of four remote sensing indicators: normalized difference vegetation index (NDVI), normalized difference built-up index (NDBI), land surface temperature (LST), and aerosol optical depth (AOD), representing the greenness, dryness, heat, and atmospheric turbidity, respectively. Combining the entropy method and random forest (RF) algorithm, the weights of four indicators were calculated. To improve the accuracy of UECIIMP, the gap-filled quarterly mean results of each indicator with 30m resolution were obtained using the harmonic analysis of time series (HANTS) method and spatial-temporal information fusion based on non-local means filter (STNLFFM). UECIIMP was applied to the Hefei-Nanjing-Hangzhou Region to explore its spatiotemporal changes and response characteristics. Results show that the weights of UECIIMP fluctuate slightly (within 10%) before and after sensitivity analysis, with good stability and reliability. UECIIMP in Hangzhou > Hefei ≈ Nanjing, spring ≈ autumn > summer ≫ winter. From 2009 to 2019, UECIIMP has improved in all 33 districts of the Hefei-Nanjing-Hangzhou Region. The significant improvement of UECIIMP in 2014–2019 is 4.3 times than that in 2009–2014. The correlation between UECIIMP and economic index indicates that economic development has a positive impact on the urban ecological environment. The significant degradation of UECIIMP in the urban expansion area demonstrates a negative impact on the local environment from urban expansion. •UECIIMP is an index based on UECI and completely derived from remote sensing images.•Combining entropy method and random forest method to calculate the weights of indicators of UECIIMP.•Time series reconstruction and spatiotemporal fusion algorithms were used to improve the data quality of UECIIMP.•UECIIMP was applied to Hefei-Nanjing-Hangzhou region from 2009 to 2019 for its ecological environment assessment.•The application of UECIIMP shows that it has the potential to be applied in different cities or regions.
doi_str_mv 10.1016/j.jenvman.2022.116533
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A rapid and objective urban ecological environment assessment (UEEA) plays an important role in the urban sustainable development and environment protection. This study established an improved urban ecological comfort index (UECIIMP), which is based on our previous UECI and fully composed of four remote sensing indicators: normalized difference vegetation index (NDVI), normalized difference built-up index (NDBI), land surface temperature (LST), and aerosol optical depth (AOD), representing the greenness, dryness, heat, and atmospheric turbidity, respectively. Combining the entropy method and random forest (RF) algorithm, the weights of four indicators were calculated. To improve the accuracy of UECIIMP, the gap-filled quarterly mean results of each indicator with 30m resolution were obtained using the harmonic analysis of time series (HANTS) method and spatial-temporal information fusion based on non-local means filter (STNLFFM). UECIIMP was applied to the Hefei-Nanjing-Hangzhou Region to explore its spatiotemporal changes and response characteristics. Results show that the weights of UECIIMP fluctuate slightly (within 10%) before and after sensitivity analysis, with good stability and reliability. UECIIMP in Hangzhou &gt; Hefei ≈ Nanjing, spring ≈ autumn &gt; summer ≫ winter. From 2009 to 2019, UECIIMP has improved in all 33 districts of the Hefei-Nanjing-Hangzhou Region. The significant improvement of UECIIMP in 2014–2019 is 4.3 times than that in 2009–2014. The correlation between UECIIMP and economic index indicates that economic development has a positive impact on the urban ecological environment. The significant degradation of UECIIMP in the urban expansion area demonstrates a negative impact on the local environment from urban expansion. •UECIIMP is an index based on UECI and completely derived from remote sensing images.•Combining entropy method and random forest method to calculate the weights of indicators of UECIIMP.•Time series reconstruction and spatiotemporal fusion algorithms were used to improve the data quality of UECIIMP.•UECIIMP was applied to Hefei-Nanjing-Hangzhou region from 2009 to 2019 for its ecological environment assessment.•The application of UECIIMP shows that it has the potential to be applied in different cities or regions.</abstract><cop>England</cop><pub>Elsevier Ltd</pub><pmid>36308957</pmid><doi>10.1016/j.jenvman.2022.116533</doi><orcidid>https://orcid.org/0000-0002-2582-276X</orcidid><orcidid>https://orcid.org/0000-0002-2094-6480</orcidid></addata></record>
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source MEDLINE; Elsevier ScienceDirect Journals
subjects aerosols
algorithms
autumn
China
Cities
Entropy
Entropy method
environmental assessment
Environmental Monitoring - methods
environmental protection
heat
Machine Learning
normalized difference vegetation index
Random forest
Remote sensing
Remote Sensing Technology
Reproducibility of Results
spring
summer
surface temperature
sustainable development
time series analysis
turbidity
UECIIMP
Urban ecological environment assessment (UEEA)
urbanization
winter
title Combing remote sensing information entropy and machine learning for ecological environment assessment of Hefei-Nanjing-Hangzhou region, China
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