基于RS和GIS的城市化进程中河道时空演变分析——以深圳市布吉河为例

doi:10.18306/dlkxjz.2021.04.013

Abstract

Abstract:

To reveal the impact of urbanization on urban river systems, the Buji River Basin, a typical highly urbanized watershed in the Guangdong, Hong Kong and Macao Bay Area, was selected as the study area. Based on Landsat satellite images from 1988 to 2015, Google Earth high-resolution images from 2003 to 2017, the river system data in 2019, as well as literature on the river improvement projects of Shenzhen City since 1980, the characteristic indices of river channel change were constructed to evaluate the spatial and temporal evolution of the river in the process of urbanization using remote sensing data and GIS technology. The study shows that: 1) From 1988 to 2015, the land use/land cover types of the Buji River Basin changed dramatically, and the urbanization rate increased from 24.55% to 61.78%. Generally, the urbanization showed the spatial and temporal characteristics of "fast first, then slowed", "spreading from downstream to upstream", and "developing along the river then towards the periphery". With the development of urbanization, the improvement of the Buji River has gone through four stages: pre-improvement, flood control measures, flood control and ecological restoration measures, and dredging measures. 2) The spatial and temporal evolution of the river was affected by urbanization. The increase of population and GDP has a driving effect on the river channel change. Different urbanization processes in different places have had different impacts on the river system, and urbanization has had different impacts on the main stream and tributaries of the Buji River. 3) On the whole, from 2003 to 2017, the proportion of surface channel, bending coefficient of surface channel, and river surface rate of the Buji River decreased by 19.06%, 9.63%, and 1.79%, respectively, which were negatively correlated with urbanization level. The river bed hardening rate was positively correlated with urbanization level, with an increase of 6.47%. This study provides a reference and theoretical support for river improvement and flood control and disaster reduction in urbanized areas of China.

Key words: satellite remote sensing, urbanization, land use/land cover change, river channel change, Buji River Basin

LIU Zexing, CHEN Yangbo. Spatiotemporal change of urban river in urbanization process based on remote sensing and GIS: A case study of the Buji River in Shenzhen City[J].PROGRESS IN GEOGRAPHY, 2021, 40(4): 693-702.

Figures/Tables 11

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References 31

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序号	工程名称	开始年份	结束年份	工程位置	具体河段	工程内容
1	深圳河及布吉河治理	1980	1985	下游	笋岗滞洪区、笋岗滞洪区泄洪闸至蔡屋围	滞洪区建设;河道截弯取直、拓宽
2	笋岗泄洪区及排沙道建设及整改	1981	1991	下游	笋岗泄洪区	泄洪区及排沙道建设及整改
3	布吉河河段整治	1987	—	下游	草铺铁路桥至笋岗滞洪区	—
4	布吉河蔡屋围水闸拆除工程	1993	—	下游	蔡屋围	拆除水闸、拓宽河段
5	布吉河下游清淤工程	1993	1996	下游	草埔北桥至笋岗泄洪闸段	河道截弯取直
6	罗湖小区治涝工程	1995	—	下游	河口	建设泵站、挡潮闸、河口堤防
7	布吉河(龙岗段)综合整治工程	2006	2006	上游	龙岗区河段	河堤修复、治理沿河污染源
8	布吉河(特区内)水环境综合整治工程	2009	2016	下游	罗湖区河段	水质改善、防洪、生态、景观等,综合治理
9	布吉河(龙岗段)“EPC+O”项目	2017	2021	上游	龙岗区河段	河道防洪、水质改善及水生态修复
10	布吉河泥岗桥至河口段(罗湖段)清淤工程	2018	2018	下游	罗湖区河段	河道清淤

序号	级别	日期	分辨率/m
1	18	2003-02-17	0.55
2	19	2010-04-30	0.28
3	19	2011-80-31	0.28
4	19	2012-11-06	0.28
5	19	2013-11-01	0.28
6	19	2014-11-17	0.28
7	19	2015-04-14	0.28
8	19	2016-07-29	0.28
9	19	2017-02-18	0.28

地区	1988年	1993年	1996年	1999年	2001年	2005年	2008年	2011年	2013年	2015年
上游地区	2.85	5.27	9.28	13.35	14.06	17.01	17.14	17.84	19.13	19.73
下游地区	12.06	12.33	15.43	17.08	16.15	15.03	16.07	16.79	17.86	17.80
总计	14.91	17.60	24.71	30.44	30.21	32.04	33.21	34.63	36.99	37.53

特征参数	2003年	2010年	2017年	变化幅度/%
特征参数	2003年	2010年	2017年	2003—2010年	2010—2017年	2003—2017年
地表河道比例/%	41.29	34.22	33.42	-17.12	-2.34	-19.06
地表河道弯曲系数	1.35	1.24	1.22	-8.15	-1.61	-9.63
河床硬化率/%	86.84	91.72	92.46	5.62	0.81	6.47
河面率/%	0.56	0.56	0.55	0	-1.79	-1.79

Spatiotemporal change of urban river in urbanization process based on remote sensing and GIS: A case study of the Buji River in Shenzhen City

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