Power line extraction using airborne LiDAR point clouds characteristics and model fitting method

doi:10.7523/j.issn.2095-6134.2018.05.007

›› 2018, Vol. 35 ›› Issue (5): 612-616.DOI: 10.7523/j.issn.2095-6134.2018.05.007

Previous Articles Next Articles

Power line extraction using airborne LiDAR point clouds characteristics and model fitting method

YANG Yuan¹, CHEN Fengxiang¹, GUO Tao¹, SHI Lei¹, WANG Cheng², LUO Xin³

1. Transmission Line Maintenance Operation Branch of Guizhou Power Grid Co., Ltd, Guiyang 550002, China;
2. Key Lab of Digital Earth Science, Institute of Remote Sensing and Digital Earth, Chinese Academy of Sciences, Beijing 100094, China;
3. Guizhou Electric Power Design & Research Institute, Guiyang 550002, China

Received:2017-07-03 Revised:2017-09-27 Online:2018-09-15

Abstract

Abstract: Digital power line is a core part of digital grid construction and smart line security inspection. Airborne LiDAR has a unique advantage for power line reconstruction because it is capable of accurately and quickly obtaining 3-D information. We propose a new method for automatically and rapidly extracting power lines from airborne LiDAR data in the transmission corridor. Firstly, the power line points were roughly extracted based on the spatial distribution of raw point clouds, and the noise points were removed by using the improved Hough transform and RANSAC parabolic fitting method. Then, the power lines were distributed on the horizontal plane and the vertical plane. Finally, the points of power line were extracted by the model growth method, which was based on the assumption that the plane model of single power line was linear and the model on the vertical plane was parabolic. The experimental results show that the extraction accuracy of power line reaches 99.6% using the proposed method.

Key words: airborne LiDAR, power line, improved Hough transform, RANdom SAmple Consensus

CLC Number:

P237

YANG Yuan, CHEN Fengxiang, GUO Tao, SHI Lei, WANG Cheng, LUO Xin. Power line extraction using airborne LiDAR point clouds characteristics and model fitting method[J]. , 2018, 35(5): 612-616.

References

[1] 王和平, 夏少波, 谭弘武, 等. 电力巡线中机载激光点云数据处理的关键技术[J]. 地理空间信息, 2015, 13(5):59-62.
[2] Ussyshkin R V, Theriault L, Sitar M, et al. Advantages of airborne LiDAR technology in power line asset management[C]//Proceedings of the 2011 International Workshop on Multi-Platform/Multi-Sensor Remote Sensing and Mapping (M2RSM), Xiamen, China, Jan 10-12, 2011:1-5.
[3] Clode S, Rottensteiner F. Classification of trees and power-lines from medium resolution airborne laser-scanner data in urban environments[J]. Clinical Therapeutics, 2005, 34(5):1145-1158.
[4] Cheng L, Tong L, Wang Y, et al. Extraction of urban power lines from vehicle-borne LiDAR data[J]. Remote Sensing, 2014, 6(4):3302-3320.
[5] Melzer T, Briese C. Extraction and modeling of power lines from ALS point clouds[C]//Proceedings of Workshop, 28th Workshop of the Austrian Association for Pattern Recognition (OAGM), Hagenberg, Austria, Jun 17-18, 2004:47-54.
[6] 叶岚, 刘倩, 胡庆武. 基于LiDAR点云数据的电力线提取和拟合方法研究[J]. 测绘与空间地理信息, 2010, 33(5):30-34.
[7] 余洁, 穆超, 冯延明, 等. 机载LiDAR点云数据中电力线的提取方法研究[J]. 武汉大学学报(信息科学版), 2011, 36(11):1275-1279.
[8] 尹辉增, 孙轩, 聂振钢. 基于机载激光点云数据的电力线自动提取算法[J]. 地理与地理信息科学, 2012, 28(2):31-34.
[9] 韩文军, 阳锋, 彭检贵. 激光点云中电力线的提取和建模方法研究[J]. 人民长江, 2012, 43(8):18-21.
[10] 陈驰, 麦晓明, 宋爽, 等. 机载激光点云数据中电力线自动提取方法[J]. 武汉大学学报(信息科学版), 2015, 40(12):1600-1605.
[11] 王平华, 习晓环, 王成, 等. 机载激光雷达数据中电力线的快速提取[J]. 测绘科学, 2017, 42(2):154-158.
[12] 阿布来提·依布拉音, 王治强, 刘薇, 等. 基于Hough直线检测的深度图像配准方法[J]. 中国科学院研究生院学报, 2013, 30(1):112-116.

Power line extraction using airborne LiDAR point clouds characteristics and model fitting method

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 2

Recommended Articles

Metrics

Comments

[1]	ZHANG Su, QI Lizhong, HAN Wenjun, ZHU Xiaoxiao, XI Xiaohuan, WANG Cheng, WANG Pu, NIE Sheng. Danger tree detection and tree number estimation based on UAV LiDAR data [J]. , 2020, 37(6): 760-766.
[2]	LI Liang, WANG Cheng, LI Shihua, XI Xiaohuan. Building roof point extraction based on airborne LiDAR data [J]. , 2016, 33(4): 537-541.