Continuous Extraction of Subway Tunnel Cross Sections Based on Terrestrial Point Clouds

Zhang, Kang; Zhang, Liqiang; Tuo, Lei; Wang, Baoqian; Chen, Jinlei

doi:10.3390/rs6010857

Cited by 60 publications

(58 citation statements)

References 16 publications

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“…The use of the TLS technique has also become popular in tunnel engineering due to the various advantages over conventional geodetic devices, such as laser beam profilers and total stations, which take more time to acquire data [12] and cannot offer high- density 3D datasets. The existing applications of TLS for tunnels contain geological feature detection [13], deformation analysis [14,15,16], and cross-sectional extraction [12,17], and the automatic processing of tunnel point clouds has received increasing research attention [12,18]. …”

Section: Introductionmentioning

confidence: 99%

Automatic Extraction of Tunnel Lining Cross-Sections from Terrestrial Laser Scanning Point Clouds

Cheng

Qiu

Jin

2016

Sensors

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Tunnel lining (bare-lining) cross-sections play an important role in analyzing deformations of tunnel linings. The goal of this paper is to develop an automatic method for extracting bare-lining cross-sections from terrestrial laser scanning (TLS) point clouds. First, the combination of a 2D projection strategy and angle criterion is used for tunnel boundary point detection, from which we estimate the two boundary lines in the X-Y plane. The initial direction of the cross-sectional plane is defined to be orthogonal to one of the two boundary lines. In order to compute the final cross-sectional plane, the direction is adjusted twice with the total least squares method and Rodrigues’ rotation formula, respectively. The projection of nearby points is made onto the adjusted plane to generate tunnel cross-sections. Finally, we present a filtering algorithm (similar to the idea of the morphological erosion) to remove the non-lining points in the cross-section. The proposed method was implemented on railway tunnel data collected in Sichuan, China. Compared with an existing method of cross-sectional extraction, the proposed method can offer high accuracy and more reliable cross-sectional modeling. We also evaluated Type I and Type II errors of the proposed filter, at the same time, which gave suggestions on the parameter selection of the filter.

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Section: Introductionmentioning

confidence: 99%

Automatic Extraction of Tunnel Lining Cross-Sections from Terrestrial Laser Scanning Point Clouds

Cheng

Qiu

Jin

2016

Sensors

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“…And then, the method of Kang (Kang et al, 2014) is used to calculate the projection point set of center axis in XOY plane named Uxoy.…”

Section: Extraction Of Central Axis Points On Xoy Planementioning

confidence: 99%

“…In order to improve the accuracy of the central axis, a method of Kang (Kang et al, 2014) And then the method of 2.1 is used to calculate the central axis point set Uyoz. In order to avoid the problem that the point clouds are sheltered by device in data acquisition process, we moved the point set Uxoy to the left (or right) for a certain distance τ before searching for the highest and lowest points (the red arrow shown in the figure), and the size of τ must bigger than radius of the orbit and smaller than inner radius of tunnel.…”

Section: Boundary Point Set Detectionmentioning

confidence: 99%

“…Carrying out precise, fast and automated deformation monitoring of the subway, especially the subway in operation is so necessary. Although the accuracy of traditional deformation monitoring method (such as total station, convergence meter and so on) for subway tunnel is MMS can obtain absolute coordinates of point cloud directly, it is usually need to rotate the tunnel point clouds and make it parallel to a certain axis before projecting them onto 2D plane (Kang et al, 2014), the process is eliminated in our method and the amount of computation is reduced. Secondly, the construction speed of cross sectional point set is increased by constructing the buffer of each section in the method of k-nearest neighbor.…”

Section: Introductionmentioning

confidence: 99%

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Automatic Monitoring of Tunnel Deformation Based on High Density Point Clouds Data

Zhong

Sun

et al. 2017

Int. Arch. Photogramm. Remote Sens. Spatial Inf. Sci.

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ABSTRACT:An automated method for tunnel deformation monitoring using high density point clouds data is presented. Firstly, the 3D point clouds data are converted to two -dimensional surface by projection on the XOY plane, the projection point set of central axis on XOY plane named Uxoy is calculated by combining the Alpha Shape algorithm with RANSAC ( Random Sampling Consistency ) algorithm, and then the projection point set of central axis on YOZ plane named Uyoz is obtained by highest and lowest points which are extracted by intersecting straight lines that through each point of Uxoy and perpendicular to the two -dimensional surface with the tunnel point clouds, Uxoy and Uyoz together form the 3D center axis finally. Secondly, the buffer of each cross section is calculated by K-Nearest neighbor algorithm, and the initial cross-sectional point set is quickly constructed by projection method. Finally, the cross sections are denoised and the section lines are fitted using the method of iterative ellipse fitting. In order to improve the accuracy of the cross section, a fine adjustment method is proposed to rotate the initial sectional plane around the intercept point in the horizontal and vertical direction within the buffer. The proposed method is used in Shanghai subway tunnel, and the deformation of each section in the direction of 0 to 360 degrees is calculated. The result shows that the cross sections becomes flat circles from regular circles due to the great pressure at the top of the tunnel.

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“…A variety of LiDAR techniques have emerged, and LiDAR data are often acquired from various platforms, for example airborne [2,3], mobile [4,5] and terrestrial platforms [6,7]. Acquiring data from a side view, terrestrial LiDAR can obtain detailed facade information of objects at relatively high resolution.…”

Section: Introductionmentioning

confidence: 99%

Shiftable Leading Point Method for High Accuracy Registration of Airborne and Terrestrial LiDAR Data

Cheng

Tong

et al. 2015

Remote Sensing

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Abstract:A new automated approach to the high-accuracy registration of airborne and terrestrial LiDAR data is proposed, which has three primary steps. Firstly, airborne and terrestrial LiDAR data are used to extract building corners, known as airborne corners and terrestrial corners, respectively. Secondly, an initial matching relationship between the terrestrial corners and airborne corners is automatically derived using a matching technique based on maximum matching corner pairs with minimum errors (MTMM). Finally, a set of leading points are generated from matched airborne corners, and a shiftable leading point method is proposed. The key feature of this approach is the implementation of the concept of shiftable leading points in the final step. Since the geometric accuracy of terrestrial LiDAR data is much better than that of airborne LiDAR data, leading points corresponding to anomalous airborne corners could be modified for the improvement of the geometric accuracy of registration. OPEN ACCESSRemote Sens. 2015, 7 1916The experiment demonstrates that the proposed approach can advance the geometric accuracy of two-platform LiDAR data registration effectively.

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Continuous Extraction of Subway Tunnel Cross Sections Based on Terrestrial Point Clouds

Cited by 60 publications

References 16 publications

Automatic Extraction of Tunnel Lining Cross-Sections from Terrestrial Laser Scanning Point Clouds

Automatic Extraction of Tunnel Lining Cross-Sections from Terrestrial Laser Scanning Point Clouds

Automatic Monitoring of Tunnel Deformation Based on High Density Point Clouds Data

Shiftable Leading Point Method for High Accuracy Registration of Airborne and Terrestrial LiDAR Data

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