Share:


Mobile laser scanning elevation data accuracy in closed and partially open sky area

    Gerly Annok   Affiliation
    ; Valdar Tammin Affiliation
    ; Natalja Liba   Affiliation

Abstract

Mobile laser scanning is being used more often in Estonia and abroad to obtain geospatial information. As the system is still new and being upgraded, different methods are being used to find out how accurately the mobile laser scanner can measure in different conditions. In this article the mobile laser scanner accuracy is being examined depending on surrounding environment and the importance of postprocessing. Mobile laser scanning elevation data accuracy obtained in difficult conditions is being assessed. Difficult conditions are considered locations where there are tall objects that interrupt the satellite signals’ trajectory to the receiver. To determine the elevation accuracy of mobile laser scanner data, coordinates with the raw broadcast and final ephemerides with the combination of the GNSS receivers’ data that were installed in ideal and not ideal environmental conditions were computed.


As a result of the study, the error of the elevation data in the first polygon, situated in difficult conditions was 7 mm when the Kunda reference station data was used with raw broadcast and final ephemerides. Error in the second polygon was accordingly 17 mm and 19 mm. When calculations were conducted using raw broadcast ephemerides in a base station in an imperfect environment, the error in the first polygon was 103 mm and in the second 75 mm. When the precise ephemerides were added to base station data, the error in the first polygon was 6 mm and in the second 21 mm. From the study results, it could be concluded that the mobile laser scanning system measures within 2 cm accuracy even in a complicated environment.

Keyword : mobile laser scanning, point cloud, kinematic measuring, elevation accuracy

How to Cite
Annok, G., Tammin, V., & Liba, N. (2021). Mobile laser scanning elevation data accuracy in closed and partially open sky area. Geodesy and Cartography, 47(1), 21-26. https://doi.org/10.3846/gac.2021.12044
Published in Issue
Mar 31, 2021
Abstract Views
448
PDF Downloads
422
Creative Commons License

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

References

Annok, G. (2017). Mobiilse laserskaneerimise kõrguslik täpsus metsa ja lageda ala korral [Mobile laser scanning elevation data accuracy in forest and open sky areas] [Bachelor’s thesis]. Estonian University of Life Sciences Institute of Forestry and Rural Engineering, Tartu, Estonia. http://dspace.emu.ee/xmlui/bitstream/handle/10492/3261/Annok_Gerly_BA2017.pdf?sequence=1&isAllowed=y

Annok, G. (2019). Mobiilse laserskaneerimise kõrguslik täpsus kinnise ja osaliselt avatud taevalaotuse korral [Mobile laser scanning elevation data accuracy in closed and partially open sky area] [Master’s thesis]. Estonian University of Life Sciences Institute of Forestry and Rural Engineering, Tartu, Estonia.

Applanix Corporation. (2014). POSPac MMS GNSS-Inertial Tools user guide. Richmond Hill, ON, Canada.

Cox, C. (2016). Mobile Mapping System: a buyer’s guide. https://slidelegend.com/queue/mobile-mapping-systems-3dlaser-mapping_59b78bfd1723ddf2725f174c.html

Geavis. (2018). What are the characteristics and differences between RTK and PPK drone? https://www.geavis.si/en/2018/03/characteristics-differences-rtk-and-ppk-drone/

Hybrid Mobile Laser Mapping System. (2014). Riegl VMZ. http://www.riegl.com/nc/products/mobile-scanning/produktdetail/product/scanner/44/

International GNSS Service. (2019). Products. http://www.igs.org/products

Løvås, M. (2017). Increasing the accuracy of positioning in Mobile Mapping Systems [Master’s thesis]. Norwegian University of Science and Technology, Trondheim, Norway.

Narayana, K. (2011). Solutions for the localization of Mobile Mapping Systems in structures environments [Doctor’s thesis]. MINES ParisTech, Paris Institute of Technology, Paris, France.

Puente, I., Gonzalez-Jorge, H., Arias, P., & Armesto, J. (2011). Land-based mobile laser scanning systems: a review. Spain.

Putnik, M. (2018). Mobiilse laserskaneerimise tehnoloogia rakendamine teekatendite mõõdistamisel [Application of mobile laser scanning technology for surveying road surfaces]. Geodeet, (48), 11–22.

Riegl. (2014). Riegl VZ-400 specification. http://www.riegl.com/uploads/tx_pxpriegldownloads/10_DataSheet_VZ-400_2017-06-14.pdf

Soe, H. (2016). Käikude mõõtmine erinevate meetoditega ja tasandusarvutused tavameetodiga ning range tasandamisega [Transverse surveying procedure with various methods and alignment calculations using the conventional method and strict alignment] [Thesis]. Tallinn University of Applied Sciences, Institute of Construction.

Szulwic, J., & Tysiąc, P. (2017). Searching for road deformations using mobile laser scanning. MATEC Web of Conferences, 122, 1–7. https://doi.org/10.1051/matecconf/201712204004

Szulwic, J., & Tysiąc, P. (2018). Mobile laser scanning calibration on a marine platform. Polish Maritime Research, 25, 159–165. https://doi.org/10.2478/pomr-2018-0037

Topcon. (2015). Sokkia GCX2 specification. https://www.topcon.co.jp/en/positioning/sokkia/products/pdf/GCX2_E.pdf

Trimble. (2010). Trimble BD982 specification. http://trl.trimble.com/docushare/dsweb/Get/Document-867958/

Trimble. (2017). Trimble R8s specification. https://geospatial.trimble.com/sites/default/files/2019-03/Datasheet%20-%20Trimble%20R8s%20GNSS%20System%20-%20English%20A4%20-%20Screen.pdf