APPLICATION OF HIGH RESOLUTION AIRBORNE LIDAR IN XIAOJIANG ACTIVE TECTONICS AND GEOLOGICAL DISASTER STUDY

LIU Yu-ping; LIANG Hong; CHENG Fi-fi

Volume 22 Issue 3

Sep. 2016

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LIU Yu-ping, LIANG Hong, CHENG Fi-fi, 2016. APPLICATION OF HIGH RESOLUTION AIRBORNE LIDAR IN XIAOJIANG ACTIVE TECTONICS AND GEOLOGICAL DISASTER STUDY. Journal of Geomechanics, 22 (3): 747-759.

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LIU Yu-ping, LIANG Hong, CHENG Fi-fi, 2016. APPLICATION OF HIGH RESOLUTION AIRBORNE LIDAR IN XIAOJIANG ACTIVE TECTONICS AND GEOLOGICAL DISASTER STUDY. Journal of Geomechanics, 22 (3): 747-759.

Citation:

LIU Yu-ping, LIANG Hong, CHENG Fi-fi, 2016. APPLICATION OF HIGH RESOLUTION AIRBORNE LIDAR IN XIAOJIANG ACTIVE TECTONICS AND GEOLOGICAL DISASTER STUDY. Journal of Geomechanics, 22 (3): 747-759.

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APPLICATION OF HIGH RESOLUTION AIRBORNE LIDAR IN XIAOJIANG ACTIVE TECTONICS AND GEOLOGICAL DISASTER STUDY

Chengdu Center, China Geological Survey, Chengdu 610081, China

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Received: 2016-04-11
Published: 2016-09-01

Abstract

Abstract

By processing airborne LiDAR flight data of Jinsha River and Xiaojiang, we obtained high precision Digital Elevation Model (DEM) and Digital Surface Model (DSM). Using the digital terrain in geological structure interpretation, we may determine the distribution of active faults and the characteristics of tectonic geomorphology, delineating the range of the landslide and debris flow in Jinsha River and Xiaojiang, also estimating the area and volume of the landslide and debris flow. High precision airborne LiDAR data provides reliable information for such geological disaster warning.
- LiDAR,
- DEM,
- Xiaojiang fracture,
- active faults,
- debris flow

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References(13)

References

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