Prior calculation of the accuracy of monitoring of cultural heritage objects using UAVs and laser scanning
Abstract
In the last few years, intensive measures have been taken to monitor and inventory the cultural heritage of Ukraine. An important aspect is the preservation of such objects and their transmission to future generations. It is important to use such a methodology and technology when performing monitoring works, which in the future will make it possible to perform a number of other tasks, in relation to a certain specific object, based on previously obtained data. Therefore, this paper proposes a method of cultural heritage monitoring using UAV-filming.
The work examines the methods of monitoring cultural heritage objects and presents an a priori assessment of the accuracy of monitoring of cultural heritage by means of UAV photography and laser scanning. The work focuses on the fact that the monitoring of cultural heritage sites should be carried out precisely with the help of modern filming methods, which have a number of advantages compared to traditional methods. The reliability of the proposed methods is presented and substantiated by calculating an a priori estimate of the accuracy of potential results.
Keyword : a priori assessment of accuracy, root mean square error (RMS), point cloud, terrestrial laser scanning, UAV surveying, objects of cultural heritage (OСH)
This work is licensed under a Creative Commons Attribution 4.0 International License.
References
Bolognesi, M., Furini, A., Russo, V., Pellegrinelli, A., & Russo, P. (2015). Testing the low-cost RPAS potential in 3D cultural heritage reconstruction. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XL-5/W4, 229–235. https://doi.org/10.5194/isprsarchives-XL-5-W4-229-2015
Chumak, O., Gorkovchuk, J., & Gorkovchuk, D. (2022). Research of algorithms for generating point clouds with various software tools on the example of the monument to Bohdan Khmelnytsky. https://www.fig.net/resources/proceedings/fig_proceedings/fig2022/papers/ts02c/TS02C_chumak_gorkovchuk_et_al_11381_abs.pdf
Glotov, V. M., & Chyzhevsky, V. V. (2005). An improved method of determining the distortion of digital shooting systems. Bulletin of Geodesy and Cartography, 2, 42–45.
Glotov, V., & Pashchetnyk, O. (2008). Analysis of the effect of errors of internal orientation elements in short-baseline stereophotogrammetric surveying. Modern Achievements of Geodetic Science and Production, II(16), 117–122.
Glotov, V., & Smoliy, K. (2008). Research of the technology of drawing up frontal plans of architectural structures by terrestrial digital surveying and laser scanning. Geodesy, Cartography and Aerial Photography, 70, 46–50.
Hassani, F., & Rafiee, M. (2013). An experience in cultural heritage documentation in Iran using a low-cost technique. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, XL-5/W2, 313–318. https://doi.org/10.5194/isprsarchives-XL-5-W2-313-2013
Lobanov, A. N. (1972). Analytical photogrammetry. Nedra Publishing House.
Roy, D. N. (2007). The experience of using the ground laser scanning method for works in the field of historical and cultural heritage. Geoprofes, 2, 20–23.
Shults, R., Krelshtein, P., Kravchenko, I., Rogoza, O., & Kyselov, O. (2017, April 27–28). Low-cost photogrammetry for cultural heritage. In “Environmental Engineering” 10th International Conference (pp. 1–8), Vilnius Gediminas Technical University, Lithuania. https://doi.org/10.3846/enviro.2017.237
Zolotova, E. (2009). Contemporary architectural measurements of real estate objects. “Architecture-S” Publishing House.