Powerline inspection is an important task for electric power management. Corridor mapping, i.e. the task of surveying the surroundings of the line and detecting potentially hazardous vegetation and objects, is performed by aerial LiDAR (Light Detection and Ranging) survey. To this purpose, main tasks are automatic extraction of the wires, and measurement of distance of objects close to the line. In this paper, we present a new fully-automated solution, which does not use time-consuming line fitting method, but is based on simple geometrical assumptions and relies on the fact that wire points are isolated, sparse and widely separated from all other points in the data set. In particular, we detect and classify pylons by local-maxima strategy. Then, a new reference system, having its origin on the first pylon and y-axis towards the second one, is defined. In this new reference system transverse sections of the raw point cloud are extracted; by iterating such procedure for all detected pylons we are able to detect the wire bundle. Obstacles are then automatically detected according to corridor mapping requirements. The algorithm is tested on two relevant datasets.
Fully Automatic Point Cloud Analysis for Powerline Corridor Mapping / Nardinocchi, Carla; Balsi, Marco; Esposito, Salvatore. - In: IEEE TRANSACTIONS ON GEOSCIENCE AND REMOTE SENSING. - ISSN 0196-2892. - 58:12(2020), pp. 8637-8648. [10.1109/TGRS.2020.2989470]
Fully Automatic Point Cloud Analysis for Powerline Corridor Mapping
Nardinocchi, Carla
;Balsi, Marco;Esposito, Salvatore
2020
Abstract
Powerline inspection is an important task for electric power management. Corridor mapping, i.e. the task of surveying the surroundings of the line and detecting potentially hazardous vegetation and objects, is performed by aerial LiDAR (Light Detection and Ranging) survey. To this purpose, main tasks are automatic extraction of the wires, and measurement of distance of objects close to the line. In this paper, we present a new fully-automated solution, which does not use time-consuming line fitting method, but is based on simple geometrical assumptions and relies on the fact that wire points are isolated, sparse and widely separated from all other points in the data set. In particular, we detect and classify pylons by local-maxima strategy. Then, a new reference system, having its origin on the first pylon and y-axis towards the second one, is defined. In this new reference system transverse sections of the raw point cloud are extracted; by iterating such procedure for all detected pylons we are able to detect the wire bundle. Obstacles are then automatically detected according to corridor mapping requirements. The algorithm is tested on two relevant datasets.File | Dimensione | Formato | |
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