Increasing the contrast and accuracy of localization of objects of interest on orthophotomaps of the terrain built from distorted images from an unmanned aerial vehicle

In this article, we will consider and compare methods for eliminating distortions in the original images obtained from an unmanned aerial vehicle. The main goal of these methods is to increase the contrast and accuracy of determining the coordinates of objects of interest relative to the background. To conduct the study, aerial work is performed, during which initial images of the underlying surface with different exposure times are obtained, as well as data from the unmanned aerial vehicle navigation module. Further, cameral processing of the received materials is carried out. The exact centers for photographing each image are calculated and orthophotomaps of the area are built. Then we have evaluated the contrast and accuracy of determining the coordinates of objects of interest relative to the background on the orthophotomaps of the area built from the original and restored images using various methods.

1. Zakhlebin A. S. Postroyeniye ortofotoplana mestnosti s ispol’zovaniyem BPLA vertoletnogo tipa DJI PHANTOM 4 [Creation of an orthophotomap of the area using the DJI PHANTOM 4 helicopter type UAV] // Elektronnyye Sredstva I Sistemy Upravleniya. Electronic Devices and Control Systems. 2018. No. 1–2. P. 159–161. EDN: ZEMEMP. (In Russ.).

2. Zakhlebin A. S. Metod obrabotki materialov aerofotos’yemki dlya postroyeniya geoprivyazannogo ortofotoplana mestnosti s televizionnoy kamery bespilotnogo letatel’nogo apparata DJI Phantom 4 PRO [A method of processing aerial photography materials for building a georeferenced orthomosaic of the terrain from a television camera of the unmanned aerial vehicle DJI Phantom 4 PRO] // Doklady Akademii Nauk Vysshey Shkoly Rossiyskoy Federatsii. Proceedings of the Russian Higher School Academy of Sciences. 2021. No. 4 (53). P. 26–35. DOI: 10.17212/1727-2769-2021-4-26-35. (In Russ.).

3. Kapustin V., Movchan A., Kuryachiy M. [et al.]. Activepulse television measuring systems images space-time filtration by // Journal of Physics: Conference Series. 2020. Vol. 1488. Р. 1–6. DOI: 10.1088/1742-6596/1488/1/012032. (In Engl.).

4. Gurkina E. D., Belov Yu. S. Korrektsiya razmytykh izobrazheniy [Image motion deblurring] // Mezhdunarodnyy Studencheskiy Nauchnyy Vestnik. International Student Scientific Herald. 2017. No. 5. P. 30. EDN: ZNLNGL. (In Russ.).

5. Braslavskaya O. B., Gendrina I. Yu., Kvach A. S. Sravneniye dvukh metodov rascheta funktsii razmytiya tochki i opticheskoy peredatochnoy funktsii [The comparison of two methods for determining of point spread function (PSF) and optical transfer function (OTF)] // Izvestiya vuzov. Fizika. Izvestiya vuzov. Fizika. 2013. Vol. 56, no. 9–2. P. 215–216. EDN: RWIFMF. (In Russ.).

6. Medvedkov N. V., Trubakov A. O. Issledovaniye metrik kachestva rezul’tatov inversnoy fil’tratsii Vinera dlya razmytykh i pryamolineyno smazannykh [Research of quality metrics for results of wiener inverse filtering of blurred and linear motion blurred images] // KOGRAF-2021. COGRAPH-2021. Nizhny Novgorod, 2021. P. 51–58. DOI: 10.46960/43791586_2021_51. EDN: YANYHA. (In Russ.).

7. Brejkina K. V., Umnyashkin S. V. Ocenka kachestva izobrazheniya pri kompensacii smaza po metodu Lyusi — Richardsona [Evaluation of Image Quality with Lucy-Richardson Blur Compensation] // Izvestiya vysshikh uchebnykh zavedeniy. Elektronika. News of Higher Educational Institutions. Electronics. 2020. No. 2 (25). P. 167–174. (In Russ.).

8. Danilina E. A., Elfimov V. T. Optimizatsiya resheniya zadachi vosstanovleniya izobrazheniya metodom Tikhonova [Optimization of the solution of the image restoration problem by the Tikhonov method] // Youth Scientific and Technical Bulletin. 2016. No. 2. P. 34. (In Russ.).

9. Medvedkov N. V., Trubakov A. O. Reshenie zadachi «slepoj» dekonvolyucii s pomoshch'yu geneticheskogo algoritma [Optimization of the solution to the image restoration problem using Tikhonov’s method] // KOGRAF-2022. COGRAPH-2022. Nizhny Novgorod, 2022. P. 39–47. DOI: 10.46960/kograph_2022_39. EDN: AIEBRU. (In Russ.).

10. Korobeynikov A. G., Fedosovskiy M. E., Aleksanin S. A. Razrabotka avtomatizirovannoy protsedury dlya resheniya zadachi vosstanovleniya smazannykh tsifrovykh izobrazheniy [Development of an automated procedure for solving the problem of restoring blurry digital images] // Kibernetika i Programmirovaniye. Cybernetics and Programming. 2016. No. 1. P. 270–291. DOI: 10.7256/2306-4196.2016.1.17867. EDN: VKQHCD. (In Russ.).