Change detection for mine environment based on domestic high resolution satellite images

doi:10.6046/gtzyyg.2018.03.21

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Abstract

With the development of mine monitoring technology towards the quantification and automation, the traditional remote sensing technology based on visual interpretation is not suitable for mine monitoring. In order to improve the automation of mine remote sensing monitoring and make up for deficiencies in traditional monitoring methods, the authors constructed an object-based change detection method with high degree of automation for dynamic monitoring of mine and the surrounding environment based on GF-2 remote sensing images. The method automatically selected training samples based on change vector analysis (CVA) and extracted change information by using extreme learning machine (ELM). The experimental results show that the detection accuracy of this method is 98.73%, and it can be used in the dynamic monitoring and analysis of mine environment with highly automation. Taking the typical mine and tailings pond in Miyi County of Sichuan Province as examples, the authors carried out the dynamic monitoring of mines and the surrounding areas based on GF-2 remote sensing images. The changes of mine and its surroundings were accurately detected, which verifies the feasibility of the method and provides examples for large-scale remote sensing monitoring in mine.

Keywords mine monitoring change detection GF-2 remote sensing images extreme learning machine

TP751.1

Corresponding Authors: Xiao JIN E-mail: jinxiao09@163.com

Issue Date: 10 September 2018

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	Lijuan WANG
	Xiao JIN
	Hujun JIA
	Yao TANG
	Guochao MA

Cite this article:

Lijuan WANG,Xiao JIN,Hujun JIA, et al. Change detection for mine environment based on domestic high resolution satellite images[J]. Remote Sensing for Land & Resources, 2018, 30(3): 151-158.

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https://www.gtzyyg.com/EN/10.6046/gtzyyg.2018.03.21 OR https://www.gtzyyg.com/EN/Y2018/V30/I3/151

Fig.1 Flow chart of object-based automatic change detection method

Fig.2 Images of experiment region in two periods

Fig.3 Reference change map of experiment region

Fig.4 Feature images of experiment region

Fig.5 Number of error detected pixels which were obtained by different training samples with different parameters

Tab.1 Accuracy of different change detection methods

Fig.6 Change map obtained by different methods

Fig.7 Images of Wanniangou tailing pond and the surrounding areas in two periods

Fig.8 Change map of Wanniangou tailing pond and the surrounding areas from 2015 to 2016

Fig.9 Images of Weilongzhou dump and the surrounding areas in two periods

Fig.10 Change map of Weilongzhou dump and the surrounding areas from 2015 to 2016

Fig.11 Images of Binghualan stope and the surrounding areas in two periods

Fig.12 Change map of Binglanhua stope and the surrounding areas from 2015 to 2016

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