1. 研究目的与意义
本论文研究背景:
在多云地区,构建高质量、高分辨率的区域EEQ数据集极具挑战。
现有研究未能考虑地表下垫面成分和季节因素对区域EEQ评价的影响。
考虑多云和特殊地形地貌因素,研究选取昭通市作为研究区域并评估其2000年至2020年的EEQ。
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2. 研究内容和预期目标
本论文的研究内容具体如下所示:
(1)基于多源遥感影像的昭通市2000-2020年土地利用时空变化分析;
(2)基于2000~2020年各期不同季节区域生态环境质量评价结果;
(3)基于2000~2020年考虑地表下垫面的昭通市生态环境质量评价结果;
(4)基于2000~2020年各期生态环境质量评价结果,利用转移矩阵等统计方法进行时序分析;
本论文的预期研究目标:
较为全面的了解云南省昭通市2000-2020年的生态环境质量,构建云南昭通市的多云地区EEQ评估框架,提供高质量和高分辨率的区域EEQ数据集,并且对未来的生态环境措施作出大致的规划与预估。
3. 研究的方法与步骤
本论文研究方法:
以云南昭通市为研究区域,利用2000-2020年Landsat 5amp;7amp;8四季地表反射率产品集、30m分辨率的土地利用(GLC_FCS30)数据集、ASTER GDEM数据等,构建一个新的生态环境综合评价指数(ECEI),计算生物丰度指数(BAI)、植被覆盖指数(VCI)、水网密度指数(WNDI)、土地胁迫指数(LSI)和污染负荷指数(PLI)5个方面以获得生态2010-2020年昭通市县级指数(EI),并使用标准差椭圆(SDE)计算方法、趋势分析方法对昭通市地区的生态环境质量进行准确科学的评价,并提出改善云南省昭通市地区生态环境质量的建议。
本论文研究步骤:
(1)数据获取与预处理;
(2)构建生态综合评价指数(ECEI);
(3)构建生态状况指数(EI);
(4)云南省昭通市2000-2020年土地利用时空分析;
(5)云南省昭通市2000-2020年生态环境质量时序分析;
(6)ECEI精度评估;
(7)总结与展望
4. 参考文献
论文的主要参考文献如下:
1. Schneider, A. Monitoring land cover change in urban and peri-urban areas using dense time stacks of Landsat satellite data and a data mining approach. Remote Sens. Environ. 2012, 124, 689–704.
2. Wolch, J.R.; Byrne, J.; Newell, J.P. Urban green space, public health, and environmental justice: The challenge of making cities “just green enough.”. Landsc. Urban Plan. 2014, 125, 234–244.
3. Firozjaei, M.K.; Fathololomi, S.; Kiavarz, M.; Arsanjani, J.J.; Homaee, M.; Alavipanah, S.K. Modeling the impact of the COVID-19 lockdowns on urban surface ecological status: A case study of Milan andWuhan cities. J. Environ. Manag. 2021, 286, 112236.
4. Li, Y.; Jia, L.; Wu, W.; Yan, J.; Liu, Y. Urbanization for rural sustainability—Rethinking China’s urbanization strategy. J. Clean. Prod. 2018, 178, 580–586.
5. Psomiadis, E.; Papazachariou, A.; Soulis, K.X.; Alexiou, D.S.; Charalampopoulos, I. Landslide mapping and susceptibility assessment using geospatial analysis and earth observation data. Land 2020, 9, 133.
6. Kouli, M.; Loupasakis, C.; Soupios, P.; Vallianatos, F. Landslide hazard zonation in high risk areas of Rethymno Prefecture, Crete Island, Greece. Nat. Hazards 2010, 52, 599–621.
7. Kumar, P.; Thakur, P.K.; Bansod, B.K.; Debnath, S.K. Multi-criteria evaluation of hydro-geological and anthropogenic parameters for the groundwater vulnerability assessment. Environ. Monit. Assess. 2017, 189, 564.
8. Willis, K.S. Remote sensing change detection for ecological monitoring in United States protected areas. Biol. Conserv. 2015, 182, 233–242.
9. He, F.; Gu, L.; Wang, T.; Zhang, Z. The synthetic geo-ecological environmental evaluation of a coastal coal-mining city using spatiotemporal big data: A case study in Longkou, China. J. Clean. Prod. 2017, 142, 854–866.
10. Li, S.; Bing, Z.; Jin, G. Spatially explicit mapping of soil conservation service in monetary units due to land use/cover change for the three gorges reservoir area, China. Remote Sens. 2019, 11, 468.
11. Zhang, L.; Liu, L.; Xia, Z.; Li, W.; Fan, Q. Sparse trajectory prediction based on multiple entropy measures. Entropy 2016, 18, 327.
12. Li, J.; Song, C.; Cao, L.; Zhu, F.; Meng, X.;Wu, J. Impacts of landscape structure on surface urban heat islands: A case study of Shanghai, China. Remote Sens. Environ. 2011, 115, 3249–3263.
13. Buyantuyev, A.;Wu, J. Urban heat islands and landscape heterogeneity: Linking spatiotemporal variations in surface temperatures to land-cover and socioeconomic patterns. Landsc. Ecol. 2010, 25, 17–33.
14. Xu, H.; Wang, M.; Shi, T.; Guan, H.; Fang, C.; Lin, Z. Prediction of ecological effects of potential population and impervious surface increases using a remote sensing based ecological index (RSEI). Ecol. Indic. 2018, 93, 730–740.
15. Xu, H.; Wang, Y.; Guan, H.; Shi, T.; Hu, X. Detecting ecological changes with a remote sensing based ecological index (RSEI) produced time series and change vector analysis. Remote Sens. 2019, 11, 2345.
16. Hu, X.; Xu, H. A new remote sensing index based on the pressure-state-response framework to assess regional ecological change. Environ. Sci. Pollut. Res. 2019, 26, 5381–5393.
17. Hu, X.; Xu, H. A new remote sensing index for assessing the spatial heterogeneity in urban ecological quality: A case from Fuzhou City, China. Ecol. Indic. 2018, 89, 11–21.
18. Shan,W.; Jin, X.; Ren, J.;Wang, Y.; Xu, Z.; Fan, Y.; Gu, Z.; Hong, C.; Lin, J.; Zhou, Y. Ecological environment quality assessment based on remote sensing data for land consolidation. J. Clean. Prod. 2019, 239, 118126.
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5. 计划与进度安排
毕业论文工作进度安排:
(1)研究工作准备阶段:
2024.01.01~2024.02.20:该时段为论文准备工作阶段,包括文献收集、数据收集与处理等;
2024.02.21~2024.03.20:该时段为论文开题报告撰写阶段,包括撰写开题报告、数据计算与分析;
(2)研究工作开展阶段:
2024.03.21~2024.05.01:该阶段为论文攻坚阶段,包括论文数据的处理与分析,毕业论文初稿的撰写,论文图表的绘制;
2024.05.02~2024.05.20:该阶段为论文修改阶段,包括对论文初稿中的格式、文字表达等进行雕琢阶段;
(3)毕业论文提交阶段:
2024.05.21~2024.05.30:该阶段为论文查重阶段,包括对毕业论文重复率进行查询与修改;
2024.05.31~2024.06.10:该阶段为论文最后修改与打印装订阶段,包括对论文进行最终版本的确定,修改与完善以及最终版本的打印与装订。
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