The technique of UAV-based airborne laser scanning data preliminary processing

Remote sensing

UDC:

528.721.221.6

DOI:

10.22389/0016-7126-2023-996-6-30-41

1 Altyntsev M.A.

Year:

2023

№:

996

Pages:

30-41

Siberian State University of Geosystems and Technologies

1,

Abstract:

The technique of UAV-based airborne laser scanning data preliminary processing is proposed. Its main steps, such as filtering the data, determining the calibration parameters of the survey system, strip adjustment of trajectories and point clouds are described and analyzed. The high density of a point cloud, which is the basic feature of the measurements made at low altitude, is taken into account. The study of the technique was carried out on the example of urban area data obtained with the laser scanner AGM-MS3. This information served to develop filtering and relative orientation algorithms. The initial data AGM-MS3 were also analyzed for the need to adjust them when the distance between adjacent strips is short. It is concluded that the technique can be used to process data on any territory.

Keywords:

adjustment, airborne laser scanning, filtering, point cloud, preliminary processing, unmanned aerial vehicle

References:

1. Alekseenko N. N. Primenenie tekhnologii lazernogo skanirovaniya v razlichnykh otraslyakh i na razlichnykh etapakh zhiznennogo tsikla ob"ektov. Vestnik MGSU, 2016, no. 2, pp. 62–73. DOI: 10.22227/1997-0935.2016.2.62-73.

2. Altynov A. E., Mokhammad Akel' Amin Issledovanie vliyaniya variatsii navigatsionnykh parametrov s"emochnoi sistemy (aerofotos"emki, lazernogo skanera) na tochnost' sozdaniya TsMM s pomoshch'yu imitatsionnogo modelirovaniya. Uspekhi sovremennogo estestvoznaniya, 2022, no. 5, pp. 110–120. DOI: 10.17513/use.37833.

3. Bandurin M. A., Vanzha V. V., Pestunova S. A. Primenenie tsifrovoi aerofotos"emki i vozdushnogo lazernogo skanirovaniya dlya otsenki sostoyaniya risovykh sistem. Nauchnaya zhizn', 2021, Vol. 16, no. 3, pp. 293–302. DOI: 10.35679/1991-9476-2021-16-3-293-302.

4. Gilaev D. M., Nazarov R. R. Prakticheskaya otsenka tochnosti i vozmozhnostei tekhnologii vozdushnogo lazernogo skanirovaniya s ispol'zovaniem bespilotnykh letatel'nykh apparatov. Marksheiderskii vestnik, 2021, no. 4 (143), pp. 44–48.

5. Komissarov A. V., Altyntsev M. A. Metod aktivnogo distantsionnogo zondirovaniya: lazernoe skanirovanie. Novosibirsk: SGUGiT, 2020, 254 p.

6. Medvedev V. I., Sarychev D. S., Skvortsov A. V. Predvaritel'naya obrabotka dannykh mobil'nogo lazernogo skanirovaniya v sisteme IndorCloud. SAPR i GIS avtomobil'nykh dorog, 2014, no. 2 (3), pp. 67–74. DOI: 10.17273/CADGIS.2014.2.11.

7. Novakovskii B. V., Kudryavtsev A. V., Entin A. L. Ispol'zovanie materialov vozdushnogo lazernogo skanirovaniya pri kartografirovanii rel'efa. Geoinformatika, 2020, no. 2, pp. 27–34.

8. Sogorin A. A., Bogdanets E. S. Issledovanie tochnosti vozdushnogo lazernogo skanirovaniya. Problemy razrabotki mestorozhdenii uglevodorodnykh i rudnykh poleznykh iskopaemykh, 2022, Vol. 1, pp. 479–484.

9. Shlyakhova M. M., Lakeev I. Yu. Monitoring ob"ektov neftegazovoi otrasli s pomoshch'yu vozdushnogo lazernogo skanirovaniya. Vestnik SSUGT, 2022, Vol. 27, no. 6, pp. 64–72. DOI: 10.33764/2411-1759-2022-27-6-64-72.

10. Yurchenko V. I. Osobennosti proektirovaniya aerofotos"emochnykh rabot s bespilotnogo vozdushnogo sudna. Vestnik of SSUGT, 2021, Vol. 26, no. 2, pp. 65–81. DOI: 10.33764/2411-1759-2021-26-2-65-81.

11. Axelsson P. (2000) DEM generation from laser scanner data using adaptive TIN models. International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XXXIII-4, pp. 111–118.

12. Glira P., Pfeifer N., Mandlburger G. (2016) Rigorous Strip Adjustment of UAV-based Lasers canning Data Including Time-Dependent Correction of Trajectory Errors. Photogrammetric Engineering and Remote Sensing, no. 82 (12), pp. 945–954. DOI: 10.14358/PERS.82.12.945.

13. Han X.-F., Jin J. S., Wang M.-J., Jiang W., Gao L., Xiao L. (2017) A review of algorithms for filtering the 3D point cloud. Signal Processing: Image Communication, no. 57, pp. 103–112. DOI: 10.1016/j.image.2017.05.009.

14. Jaakkola A., Hyyppä J., Kukko A., Yu X., Kaartinen H., Lehtomäki M., Lin Y. (2010) A low-cost multi-sensoral mobile mapping system and its feasibility for tree measurements. ISPRS Journal of Photogrammetry and Remote Sensing, no. 65 (6), pp. 514–522. DOI: 10.1016/j.isprsjprs.2010.08.002.

15. Simoniello T., Coluzzi R., Imbrenda V., Guariglia A. (2022) Automatic Filtering and Classification of Low-Density Airborne Laser Scanner Clouds in Shrubland Environments. Remote Sensing, no. 14 (20), pp. 5127. DOI: 10.3390/rs14205127.

Citation:

Altyntsev M.A.,

(2023) The technique of UAV-based airborne laser scanning data preliminary processing. Geodesy and cartography = Geodezia i Kartografia, 84(6), pp. 30-41. (In Russian). DOI: 10.22389/0016-7126-2023-996-6-30-41

Publication History

Received: 22.02.2023

Accepted: 22.05.2023

Published: 20.07.2023