A field surveying on the geodetic control of engineering linear structures using a terrestrial laser scanner

Andrew Pikilnyak; Oleksandr Naminat; Alena Palamar

doi:10.3846/gac.2019.6255

DOI: https://doi.org/10.3846/gac.2019.6255

Abstract

The method of geodetic control of the road pavement using TLS is presented. The use of the terrestrial laser scanner can avoid some of the disadvantages of classical methods for determining the deformation of objects. One of the main of them is a small amount of information about the position of individual parts of the object, in this case, linear engineering structures. The proposed technique for terrestrial laser scanning of pavement in order to determine its actual spatial position and real geometric shape allows to perform the required set of works with the least labor and time costs, and also to obtain data for further monitoring. The technique involves the construction of a three-dimensional model of pavement for its evaluation over a certain time interval with a similar model. In order to determine the coordinates by the TLS, the special spheres of known diameter were used. During the measurements, tribrachs on tripods were used, in which the spheres alternately changed to reflectors to eliminate the centering error. The accuracy of determining the coordinates of the temporary survey network relative to the base station was no more than ±27 mm. The accuracy estimation of the temporary survey network coordinates made in the “LeicaGeoOffice” software is presented. The network of permanent stations in Ukraine was used to determine the coordinates, the errors were calculated as the RMS deviation.

Keyword : monitoring, terrestrial laser scanner, linear structure, geodetic control, field surveying

How to Cite

Pikilnyak, A., Naminat, O., & Palamar, A. (2019). A field surveying on the geodetic control of engineering linear structures using a terrestrial laser scanner. Geodesy and Cartography, 45(2), 49-56. https://doi.org/10.3846/gac.2019.6255

Published in Issue

Sep 3, 2019

Abstract Views

1802

PDF Downloads

595

This work is licensed under a Creative Commons Attribution 4.0 International License.

References

Abellán, A., Jaboyedoff, M., Oppikofer, T., & Vilaplana, J. (2009). Detection of millimetric deformation using a terrestrial laser scanner. Experiment and application to a rockfall event. Natural Hazards Earth System Sciences, 9, 365-372. https://doi.org/10.5194/nhess-9-365-2009

Alba, M., Roncoroni, F., & Scaioni, M. (2008). Investigations about the accuracy of target measurement for deformation monitoring. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, 37(Part B5), 1053-1059.

Dumalski, A., & Hejbudzka, K. (2010, April 11-16). An attempt at using a terrestrial laser scanner for detecting minimal displacement and objects deformations. Paper presented at the Proceedings of Facing the Challenges – Building the Capacity, Sydney, Australia. Poland.

Ko, S. J., & Lee, Y. H. (1991). Center weighted median filters and their applications to image enhancement. IEEE Transactions on Circuits and Systems, 38(9), 984-993. https://doi.org/10.1109/31.83870

Leica-geosystems. (2018). Leica TPS400 Series Easy, quick, reliable and powerful. Retrieved from https://www.leica-geosystems.com/common/shared/downloads/inc/down-loader.asp?id=2226

Linh, T., & Laefer, D. (2014). Application of terrestrial laser scanner in bridge inspection: review and an opportunity. In 37th IABSE Symposium: Engineering for Progress, Nature and People (pp. 2713-2720), Madrid, Spain, 3-5 September. International Association for Bridge and Structural Engineering. https://doi.org/10.2749/222137814814070190

Meier, E., Geiger, А., Ingensand, H., Licht, H., Limpach, P., Steiger, A., & Zwyssig, R. (2010). Hydrostatic levelling system: measuring at the system limits. Journal of Applied Geodesy, 4(2), 91-102. https://doi.org/10.1515/jag.2010.009

Mill, T., & Ellmann, A. (2014, April 3-4). Terrestrial laser scanning technology for deformation monitoring of a large suspension roof structure. Paper presented at the INGEO 2014 – 6th International Conference on Engineering Surveying Prague, Czech Republic.

Ministry of Emergencies of Ukraine. (2012). Methodological recommendations for the protection of mineral resources in the development of mineral deposits (No. 1268). Retrieved from https://zakon.rada.gov.ua/rada/show/en/v1268735-12/sp:max20

Neitzel, F. (2006). Investgation of axes errors of terrestrial laser scanners. Paper presented at the 5th International Symposium Turkish-German Joint Geodetic Days, Berlin.

Ninkov, T., Bulatović, V., Sušić, Z., & Vasić, D. (2010, April 11-16). Application of laser scanning technology for civil engineering projects in Serbian. Paper presented at the FIG Congress 2010 Facing the Challenges – Building the Capacity Sydney, Australia.

Song, B., Zheng, N., Li, D., Chen, R., & Li, L. (2015). Reconstructing DEM using TLS point cloud data and NURBS surface. Transactions of Nonferrous Metals Society of China, 25(9), 165-172. https://doi.org/10.1016/S1003-6326(15)63947-4

Tsakiri, M., Lichti, D., & Pfeifer, N. (2006, May 22-24). Terrestrial laser scanning for deformation monitoring 3rd IAG. Paper presented at the 12th FIG Symposium, Baden.

Voronin, M., Sinyakin, A., & Ustyugov, M. B. (2004). External and internal effects on optical-electronic devices and their testing. Novosibirsk: SSGA.