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The study of the “Cetus” unmanned aerial vehicle for topographic aerial surveying

Abstract

The work aims to analyze and study the possibilities of using “Cetus” unmanned aerial vehicle (UAV) for performing topographic aerial surveys. The authors developed and tested aircraft-type UAV for topographic aerial photography. The studies were conducted on a specialized landfill, at which there is an appropriate number of situational points whose coordinates are determined with high accuracy. These points were used as both reference and control points. The obtained UAV aerial survey materials were subjected to a phototriangulation process to determine the orientation elements and to analyze, first and foremost, the angular orientation elements. The surveying was carried out on a mountainous territory, where the spatial coordinates of 37 situational points were determined by the method of ground-based GPS survey with an average accuracy of up to 0.05 m. These points were used as reference and control points. Aerial photography was performed in such a way that the scale of the images was as uniform as possible.


The design solutions implemented in the Cetus UAV provide all the possibilities to perform aerial surveys of territories in strict compliance with the projected flight parameters. UAV equipment provides the necessary real-time correction of the position of the aerial camera. At the same time the optimum straightness of routes, stability of scales and mutual overlapping of pictures is reached. Regarding the accuracy of obtaining the spatial coordinates of the points of terrain objects, using “Cetus” UAV surveys, plans can even be made on a scale of even 1: 1000. As a result of the creation of the UAV “Cetus”, it became possible to perform the topographic aerial survey of the territories and to create large-scale orthophotos that fully meet the instructions. As a result of testing the “Cetus” UAV, it can be used in production processes when drawing up topographic plans for a large-scale series: 1: 1000 – 1: 5000, which will significantly save the cost of performing topographic work.

Keyword : unmanned aerial vehicle, roll, pitch, drift angle, phototriangulation, accuracy assessment

How to Cite
Hlotov, V., Hunina, A., Kolb, I., Kolesnichenko, V., & Trevoho, I. (2021). The study of the “Cetus” unmanned aerial vehicle for topographic aerial surveying. Geodesy and Cartography, 47(2), 96-103. https://doi.org/10.3846/gac.2021.12120
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Aug 16, 2021
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References

Abris.Aero. (2020). https://abris.aero/abris-flightplanner-software

American Society for Photogrammetry and Remote Sensing. (2014). ASPRS positional accuracy standards for digital geospatial data (ed. 1, version 1.0). Photogrammetric Engineering & Remote Sensing, 81(3), A1–A26. https://www.asprs.org/wp-content/uploads/2015/01/ASPRS_Positional_Accuracy_Standards_Edition1_Version100_November2014.pdf

Bryson, M., Reid, A., Ramos, F., & Sukkarieh, S. (2010). Airborne vision-based mapping and classification of large farmland environments. Journal of Field Robotics, 27(5), 632–655. https://doi.org/10.1002/rob.20343

Fernández-Hernandez, J., González-Aguilera, D., Rodríguez-Gonzálvez, P., & Mancera-Taboada, J. (2015). Image-based modeling from unmanned aerial vehicle (UAV) photogrammetry: An effective, low-cost tool for archaeological applications. Archaeometry, 57(1), 128–145. https://doi.org/10.1111/arcm.12078

Hadjimitsis, D., Clayton, C., & Hope, V. (2004). An assessment of the effectiveness of atmospheric correction algorithms through the remote sensing of some reservoirs. International Journal of Remote Sensing, 25(18), 3651–3674. https://doi.org/10.1080/01431160310001647993

Haletskyi, V., Hlotov, V., Kolesnichenko, V., Prokhorchuk, O., & Tserklevych, A. (2012a). Analiz eksperymentalnykh robit z stvorennia velykomasshtabnykh planiv silskykh naselenykh punktiv pry zastosuvanni BPLA [Analysis of experimental works on creation of large-scale plans of rural settlements in the application of UAV]. Heodeziia, kartohrafiia i aerofotoznimannia, 76, 85–93.

Haletskyi, V., Hlotov, V., Kolesnichenko, V., Prokhorchuk, O., & Tserklevych, A. (2012b). Druhyi etap eksperymentalnykh robit z aeroznimannia silskykh naselenykh punktiv BPLA [The second stage of experimental work on aerial survey of rural settlements of UAV]. Heoinformatsiinyi monitorynh navkolyshnoho seredovyshcha GPS i GIS tekhnolohii: zb. nauk. mater. XVII Mizhn. nauk.-tekhn. Sympoziumu, 274–277.

Hlotov, V., Tserklevych, A., Zbrutskyi, O., Kolisnichenko, V., Prokhorchuk, O., Karnaushenko, R., & Haletskyi, V. (2014). Analiz i perspektyvy aeroznimannia z bezpilotnoho litalnoho aparata [Analysis and prospects of aerial photography from an unmanned aerial vehicle]. Suchasni dosiahnennia heodezychnoi nauky ta vyrobnytstva, 1(27), 131–136.

Hlotov, V. M., & Hunina, A. V. (2017). Sposib vyznachennia fokusnoi viddali tsyfrovoi znimalnoi kamery [A method for determining the focal length of a digital camera]. (Ukraine, Patent No. 121758). Ukrainian Patent and Trademark Office.

Hlotov, V. M., & Hunina, A. V. (2018). Sposib vyznachennia fokusnoi viddali tsyfrovoi znimalnoi kamery [A method for determining the focal length of a digital camera]. (Ukraine, Patent No. 130494). Ukrainian Patent and Trademark Office.

Hlotov, V., Hunina, A., Kolesnichenko, V., Prokhorchuk, O., & Yurkiv, M. (2018). Development and investigation of UAV for aerial surveying. Geodesy, Cartography and Aerial Photography, 87, 48–57. https://doi.org/10.23939/istcgcap2018.01.048

Kostyuk, A. (2011). Osobennosti aerofotos’emki so sverhlegkih bespilotnyih letatelnyih apparatov [Features of aerial photography from ultralight unmanned aerial vehicles]. Omskiy nauchnyiy vestnik, 1(104), 236–240.

Levytskyi, V. (2008). Udoskonalennia metodyky analitychnoi obrobky znimkiv, otrymanykh nemetrychnymy tsyfrovymy kameramy pry vykonanni fotohrammetrychnoi ziomky [Improvement of the method of analytical processing performing photogrammetric shooting]. Visnyk Zhytomyrskoho derzhavnoho tekhnolohichnoho universytetu. Tekhnichni nauky, 1(44), 154–164.

Mahiny, A. S., & Turner, B. J. (2007). A comparison of four common atmospheric correction methods. Photogrammetric Engineering & Remote Sensing, 73(4), 361–368. https://doi.org/10.14358/PERS.73.4.361

Rokhmana, C. A. (2015). The potential of UAV-based remote sensing for supporting precision agriculture in Indonesia. Procedia Environmental Sciences, 24, 245–253. https://doi.org/10.1016/j.proenv.2015.03.032

Shevenia, M. (2013). Aerofotos’emka s prymenenyem bespylotnyikh letatelnyikh apparatov (BPLA) [Aerial photography using unmanned aerial vehicles (UAVs)]. Geodesy and Cartography, 1. http://baltagp.ru/aerophoto/

Smith, G. M., & Milton, E. J. (1999). The use of the empirical line method to calibrate remotely sensed data to reflectance. International Journal of Remote Sensing, 20(13), 2653–2662. https://doi.org/10.1080/014311699211994

Tsytsokhov, D., & Boiko, O. (2014). Vykonannia topohrafoheodezychnykh robit z vykorystanniam bezpilotnykh litalnykh aparativ [Execution of topographic-geodetic works with the use of unmanned aerial vehicles]. In Second All-Ukrainian Scientific and Technical Conference of Students, Graduate Students and Young Scientists, “Youth: Science and Innovation” (Vol. 5, Section 6 – Surveying and land management). http://science.nmu.org.ua/ua/conferences/molod-nauka-ta-innov/pdf-2014/20150204-06.pdf