Study on Ecological Environment and Sustainable Land Use Based on Satellite Remote Sensing

Jiankang Zhang; Yanpei Cheng; Hua Dong; Qingshi Guo; Kun Liu; Fawang Zhang

Volume 1 Issue 1

Jun. 2013

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Article Navigation > Journal of Groundwater Science and Engineering > 2013 > 1(1): 89-96

Jiankang Zhang, Yanpei Cheng, Hua Dong, et al. 2013: Study on Ecological Environment and Sustainable Land Use Based on Satellite Remote Sensing. Journal of Groundwater Science and Engineering, 1(1): 89-96.

Citation:

Jiankang Zhang, Yanpei Cheng, Hua Dong, et al. 2013: Study on Ecological Environment and Sustainable Land Use Based on Satellite Remote Sensing. Journal of Groundwater Science and Engineering, 1(1): 89-96.

Citation:

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Study on Ecological Environment and Sustainable Land Use Based on Satellite Remote Sensing

1Institute of Hydrogeology and Environmental Geology, Chinese Academy of Geological Sciences, Shijiazhuang, China;1Remote Sensing Center of Hebei Province, Shijiazhuang, China;1Institute of Karst Geology, Chinese Academy of Geological Sciences, Guilin, China

Funds:

Supported by “Geological Environment Serial Map Compilation of Asia and Geological Environment Issues (1:5,000,000)” (1212011120137), is sponsored by China Geological Survey

Publish Date: 2013-06-28

Abstract

Abstract

GIS and RS techniques have been applied to interpret satellite data in 1992, 2000 and 2010. Further, the ecological environment factors of these three periods and the data for various types of land use have been obtained. LUDI in the Amur River Basin from 1992 to 2010 has been quantitatively analyzed by using the land use dynamic (LUDI) model and of land use transfer matrix model. The results indicated that from 1992 to 2010 the LUDI of land desertification is greatest, and is the most dramatic change. The comprehensive land use dynamic in the study area is 15.25, hence the land type is characterized by rapid change. In addition the area of woodland and farmland continues to increase, which has been mainly transformed from the mixture of forestland and grassland, marsh and wetland, this is an outcome of the production of shelter-forest plantation in North China, Northeast China and Northwest China. In the ten years period of the study, the area of desertified land has increased, changing mainly from a mixture of woodland and grassland. This study can rovide data for eco-geological environment management.
- GIS,
- RS,
- Amur River Basin,
- LUDI,
- transfer matrix,
- ecological environment

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References(12)

References

Liu Jiyuan, Zhang Zengxiang, Zhuang Dafang et al. Spatio-temporal Dynamic Changes of Land Use and Analysis of China in 1990s. Geographical Research, No.2 (2003), p.1-12. (In Chinese)

FAO. Potential Population Carrying Capacities of Land in the Developing World. Rome, (1982)

Wei Suqiong and Chen Jianfei. A Study on the Dynamic Change and Trend of Land Use in Fujian Province Journal of Fujian Normal University (Natural Science), Vol. 19, No.4 (1992), p.85-91.(In Chinese)

Li Xiubin. A Review of International Researches on Land Use/Land Cover Change. Acta Geographical Sinica, Vol. 51, No.6 (1996), p.553-558

Zheng Zhenyuan. Potential Population Carrying Capacities of land in China. China Land Science, Vol. 10,No.5 (1996), p.32-35. (In Chinese)

Yan Tailai, Wu Ping. Spatio-temporal Data Management for Land Information System with Timing Dimension [J]. China Land Science, Vol. 16, No.6 (2002), p.11-19. (In Chinese)

Xie Junqi. A Review and Prospect of Sustainable Land Management. China Land Science, Vol. 13, No.1 (1999), p.34-37.v

Shi Peijun, Gongpeng. Study Method and Practices of Land Use/Coverage Change. Beijing：Science Press, (2000).p.19-30. (In Chinese)

Study Group of China Land Resources Productivity and Population Carrying Capacities. Study on Productivity of China Land Resources and Population Carrying Capacities. Beijing: The Publishing House of Renmin University of China, (1991), p.1~125. (In Chinese)

Chen Baiming. The Comprehensive Productivity of China Agricultural Resources and Population Carrying Capacities. Beijing: Meteorology Press, (2000). (In Chinese)

Feng Zhiming and Liu Yujie. A Review and Prospect of Land Resources. Resources Science, Vol. 26,No.4 (2004), p.2-10. (In Chinese)

Zheng Shunyi, Zeng Xuegui. Land Information System Based on knowledge Engineering. China Land Science, Vol. 14, No.3 (2000), p.31-34. (In Chinese)

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