Abstract
As the railway overhead contact system (OCS) is the key component along the high-speed railway, it is crucial to detect the quality of the OCS. Compared with conventional manual OCS detection, the vehicle-mounted Light Detection and Ranging (LiDAR) technology has advantages such as high efficiency and precision, which can solve the problems of OCS detection difficulty, low efficiency, and high risk. Aiming at the contact cables, return current cables, and catenary cables in the railway vehicle-mounted LiDAR OCS point cloud, this paper used a scale adaptive feature classification algorithm and the DBSCAN (density-based spatial clustering of applications with noise) algorithm considering OCS characteristics to classify the OCS point cloud. Finally, the return current cables, catenary cables, and contact cables in the OCS were accurately classified and extracted. To verify the accuracy of the method presented in this paper, we compared the experimental results of this article with the classification results of TerraSolid, and the classification results were evaluated in terms of four accuracy indicators. According to statistics, the average accuracy of using this method to extract two sets of OCS point clouds is 99.83% and 99.89%, respectively; the average precision is 100% and 99.97%, respectively; the average recall is 99.16% and 99.42%, respectively; and the average overall accuracy is 99.58% and 99.69% respectively, which is overall better than TerraSolid. The experimental results showed that this approach could accurately and quickly extract the complete OCS from the point cloud. It provides a new method for processing railway OCS point clouds and has high engineering application value in railway component detection.
Highlights
With the rapid development of railway electrification, the reliability and safety of railway traction power equipment is a key research issue [1,2,3]
After determining the parameter values of MinPts and Eps, the DBSCAN algorithm considering the characteristics of overhead contact systems (OCS) is used to classify the OCS
The red point cloud is classified as a contact cable, the green point cloud is a catenary cable, and the pink point cloud is a return current cable
Summary
With the rapid development of railway electrification, the reliability and safety of railway traction power equipment is a key research issue [1,2,3]. The detection of railway overhead contact systems (OCS) is the key link to ensure the normal operation of railway traction electric power. Under the influence of pantograph and environmental factors, the components of OCS, such as contact cables, return current cables, and catenary cables, are prone to deformation. These deformations may cause instability of the power supply, affect the durability of components, and even cause accidents [4]. At present, determining the detection method with high efficiency, high precision, and low risk has become a research hotspot
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