Extraction of Power Line Pylons and Wires Using Airborne LiDAR Data at Different Height Levels

Awrangjeb, Mohammad

doi:10.3390/rs11151798

Cited by 44 publications

(35 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Awrangjeb [36] proposed a hierarchical approach where PLCs, pylons, and power lines were extracted in order. The PL corridors in the form of straight lines were first extracted by converting the input point cloud data at different height levels into binary images.…”

Section: Related Workmentioning

confidence: 99%

Automatic Extraction of High-Voltage Bundle Subconductors Using Airborne LiDAR Data

2020

Self Cite

View full text Add to dashboard Cite

Overhead high-voltage conductors are the chief components of power lines and their safety has a strong influence on social and daily life. In the recent decade, the airborne laser scanning (ALS) technique has been widely used to capture the three-dimensional (3D) information of power lines and surrounding objects. Most of the existing methods focused on extraction of single conductors or extracted all conductors as one object class by applying machine learning techniques. Nevertheless, power line corridors (PLCs) are built with multi-loop, multi-phase structures (bundle conductors) and exist in intricate environments (e.g., mountains and forests), and thus raise challenges to process ALS data for extraction of individual conductors. This paper proposes an automated method to extract individual subconductors in bundles from complex structure of PLCs using a combined image- and point-based approach. First, the input point cloud data are grouped into 3D voxel grid and PL points and separated from pylon and tree points using the fact that pylons and trees are vertical objects while power lines are non-vertical objects. These pylons are further separated from trees by employing a statistical analysis technique and used to extract span points between two consecutive pylons; then, by using the distribution properties of power lines in each individual span, the bundles located at different height levels are extracted using image-based processing; finally, subconductors in each bundle are detected and extracted by introducing a window that slides over the individual bundle. The orthogonal plane transformation and recursive clustering procedures are exploited in each window position and a point-based processing is conducted iteratively for extraction of complete individual subconductors in each bundle. The feasibility and validity of the proposed method are verified on two Australian sites having bundle conductors in high-voltage transmission lines. Our experiments show that the proposed method achieves a reliable result by extracting the real structure of bundle conductors in power lines with correctness of 100% and 90% in the two test sites, respectively.

show abstract

Section: Related Workmentioning

confidence: 99%

Automatic Extraction of High-Voltage Bundle Subconductors Using Airborne LiDAR Data

2020

Self Cite

View full text Add to dashboard Cite

show abstract

“…A combined connected component and histogram analysis was performed to find the individual pylons. In another work of Awrangjeb [13] the PLC was first extracted in the form of rectangular regions and pylon locations were detected by finding the gap in terms of height between vegetation and power lines. The pylon locations were used as seed regions and grown to extract the complete pylons.…”

Section: A Pylon Detection and Extractionmentioning

confidence: 99%

An improved method for pylon extraction and vegetation encroachment analysis in high voltage transmission lines using LiDAR data

Munir

Awrangjeb

Stantić

2020

2020 Digital Image Computing: Techniques and Applications (DICTA)

Self Cite

View full text Add to dashboard Cite

The maintenance of high-voltage power lines rightsof-way due to vegetation intrusions is important for electric power distribution companies for safe and secure delivery of electricity. However, the monitoring becomes more challenging if power line corridor (PLC) exists in complex environment such as mountainous terrains or forests. To overcome these challenges, this paper aims to provide an automated method for extraction of individual pylons and monitoring of vegetation near the PLC in hilly terrain. The proposed method starts off by dividing the large dataset into small manageable datasets. A voxel grid is formed on each dataset to separate power lines from pylons and vegetation. The power line points are converted into a binary image to get the individual spans. These span points are used to find nearby vegetation and pylon points and individual pylons and vegetation are further separated using a statistical analysis. Finally, the height and location of extracted vegetation with reference to power lines are estimated and separated into danger and clearance zones. The experiment on two large Australian datasets shows that the proposed method provides high completeness and correctness of 96.5% and 99% for pylons, respectively. Moreover, the growing vegetation beneath and around the PLC that can harm the power lines is identified.

show abstract

“…The authors of the paper [23] present a tower reconstruction method from LiDAR data using stochastic geometry based on a model library. Another paper [24] presents a new approach to the extraction of conductors, towers and power line corridors based on the newly developed method of Height levels. The advantage of this method is a better extraction of vertically overlapping objects, e.g., trees and conductors.…”

Section: Introductionmentioning

confidence: 99%

Advanced Power Line Diagnostics Using Point Cloud Data—Possible Applications and Limits

2021

View full text Add to dashboard Cite

The advance in remote sensing techniques, especially the development of LiDAR scanning systems, allowed the development of new methods for power line corridor surveys using a digital model of the powerline and its surroundings. The advanced diagnostic techniques based on the acquired conductor geometry recalculation to extreme operating and climatic conditions were proposed using this digital model. Although the recalculation process is relatively easy and straightforward, the uncertainties of input parameters used for the recalculation can significantly compromise such recalculation accuracy. This paper presents a systematic analysis of the accuracy of the recalculation affected by the inaccuracies of the conductor state equation input variables. The sensitivity of the recalculation to the inaccuracy of five basic input parameters was tested (initial temperature and mechanical tension, elasticity modulus, specific gravity load and tower span) by comparing the conductor sag values when input parameters were affected by a specific inaccuracy with an ideal sag-tension table. The presented tests clearly showed that the sag recalculation inaccuracy must be taken into account during the safety assessment process, as the sag deviation can, in some cases, reach values comparable to the minimal clearance distances specified in the technical standards.

show abstract

Extraction of Power Line Pylons and Wires Using Airborne LiDAR Data at Different Height Levels

Cited by 44 publications

References 21 publications

Automatic Extraction of High-Voltage Bundle Subconductors Using Airborne LiDAR Data

Automatic Extraction of High-Voltage Bundle Subconductors Using Airborne LiDAR Data

An improved method for pylon extraction and vegetation encroachment analysis in high voltage transmission lines using LiDAR data

Advanced Power Line Diagnostics Using Point Cloud Data—Possible Applications and Limits

Contact Info

Product

Resources

About