The Design and Implementation of Qinghai-Tibet Plateau Environmental and Geological Integrated Appraisement System Based on RS Data

doi:10.6046/gtzyyg.2010.s1.08

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Abstract

With Qinghai-Tibet Plateau as the study area, this zonal environmental and geological integrated appraisement

system based on RS data is mainly composed of three kinds of integrated appraisement models, i.e., Overlay Computing,

Analytic Hierarchy Process (AHP) and Fuzzy Gray Multi-method. There are three parts of components in this appraisement

system, which are modal running platform, modal spatial system and modal attribute system. With this appraisement system,

different models could be used to evaluate environmental and geological status of the same place, and the appraisement

results from different models could be analyzed separately and compared with each other. In addition, the system solves the

data conversion problem for different data types and the cartographic problem in the printing process of the appraisement

result. With this appraisement system, the researchers needn’t to open both GIS (Geographic Information System) and RS

(Remote Sensing) software at the same time to operate spatial data such as ArcGIS and ERDAS. With the adoption of Overlay

Computing Method and Fuzzy Gray Multi-method, the appraisement system selected five kinds of indexes, namely Disaster,

Hungriness, Marsh, Glacier and Fault, in the Qinghai-Tibet Plateau to evaluate local environmental and geological status.

It is proved that the appraisement result is well consistent with the field survey data.

Keywords Dong ting lake Equation Storing floodwater Evaluating

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Issue Date: 13 November 2010

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	LI Xiang-lian
	CHEN Jin-ai

Cite this article:

LI Xiang-lian,CHEN Jin-ai. The Design and Implementation of Qinghai-Tibet Plateau Environmental and Geological Integrated Appraisement System Based on RS Data[J]. REMOTE SENSING FOR LAND & RESOURCES, 2010, 22(s1): 30-34.

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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2010.s1.08 OR https://www.gtzyyg.com/EN/Y2010/V22/Is1/30

［1］中国地质调查局工作标准.区域环境地质调查总则（试行）［S］.DD 2004-02.

［2］王明章. 论喀斯特生态地质环境及其研究意义［J］. 贵州地质，2004，21（4）：251-253.

［3］张征，沈珍瑶，韩海荣，等.环境评价学［M］.北京：高等教育出版社，2005.

［4］黄润华，贾振邦.环境评价基础教程［M］.北京：高等教育出版社，2003.

［5］周兴.AHP法在广西生态环境综合评价中的应用［J］.广西师范学院学报（自然科学版），2003，20（3）：8-15.

［6］张建民，孙中庆，等.黄河三角洲生态环境遥感分析与应用评价［C］∥2005遥感科技论坛文集.北京：中国宇航出版社，2005，217-

223.

［7］李满春，任建武，等.GIS设计与实现［M］.北京：科学出版社，2003.

［8］张友生.软件体系结构［M］.北京：清华大学出版社，2004.

［9］和正民，王建超，燕云鹏，等.基于ArcGIS的青藏高原生态地质环境遥感监测系统［J］.国土资源遥感，2006（2）：75-78.

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[5]	LI Xiang-lian, CHEN Jin-ai . THE FORMULATION OF A CORRELATION EQUATION FOR ESTIMATING LEVEL,AREA AND VOLUME OF THE DONGTING LAKE AND THE EVALUATION OF ITS CAPACITY OF REGULATING AND STORING FLOODWATER[J]. REMOTE SENSING FOR LAND & RESOURCES, 2002, 14(1): 57-60.
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