Open Information and Computer Integrated Technologies

The subject of study. A new algorithm for real-time data compression in a video surveillance system from an unmanned aerial vehicle is proposed. The algorithm makes it possible to obtain different degrees of video data compression using different codecs for specific video recording conditions (UAV altitude and flight speed, nature of the observed terrain, etc.), and also provides the ability to transmit video data to the flight control point via radio channel. A detailed analysis of the quality of the proposed algorithm for shooting in various video formats that meet international standards (HD and Full HD) was carried out, both in terms of visual perception and objective criteria. The purpose of the study was to conduct a comprehensive research on the problem of improving the quality of the video surveillance system from the UAV and to create a video compression algorithm that allows broadcasting video data to the control center in real time with high quality. Objectives. To develop and programmatically implement a video compression algorithm based on modern codecs for video surveillance sys­tems on board a UAV. To use modern video cameras and a microcomputer platform as hardware. To analyze the quality indicators of the algorithm in different conditions. Methods used. Evaluation of visual perception of video compression results, statistical analysis and processing of the parameters of the analyzed video sequence as a random spatio-temporal process. Results. A new video data compression algorithm for the UAV video surveillance system based on the Raspberry Pi 5 microcomputer using modern video compression codecs H.264 and H.265 was synthesized. The algorithm provides the required compression ratio and data transmission rate over the radio channel between the UAV and the flight control center. Detailed estimates of the quality of the algorithm are obtained. Conclusions. Scientific novelty of the results: A new universal video data compression algorithm for video surveillance systems on board UAVs with the ability to transmit video over a radio channel in real time has been proposed and implemented. The quality of the proposed algorithm is verified on real video surveillance results. The proposed algorithm is implemented in the Python software environment.

STANAG 7023/AEDP-9 NATO Primary Image Format. Available at: www.nato.int/structur/AC/224/ standard/ 7023/7023.htm (accessed 15.10.2024).

STANAG 4607/AEDP-7. NATO Ground Moving Target Indicator Format. (GMTIF). Available at: www.nato.int/structur/AC/224/standard/4607/4607.htm (accessed 15.10.2024).

STANAG 7085. Interoperable Data Links for Imaging Systems. Available at: www.nato.int/structur/AC/224/standard/7023/7023.htm (accessed 20.10.2024).

STANAG 4609/AEDP-8. NATO Digital Motion Imagery Format. Available at: www.nato.int/structur/AC/224/standard/4609/4609.htm (accessed 20.10.2024).

Pyung-Joo Park et al. Performance of UAV (Unmanned Aerial Vehicle) Communication System Adapting Wi Bro with Array Antenna. – Proceedings of the 11th international conference on Advanced Communication Technology, Volume 2, Feb.15-18 2009, p. 1233–1237.

Tom Nelson, Michael Rice, Michael Jensen. Experimental Results for Space-Time Coding Using ARTM Tier-1 Modulation. – Proceedings of the International Telemetering Conference, Las Vegas, NV, October 2005, pp. 90-100.

Chinese Patent № CN 113872667A, МПК H01Q 1/24; H01Q 3/02. Published 31.12.2021. Available at: https://worldwide.espacenet.com/patent/ search/family/078994020/publication/CN113872667A?q=pn%3DCN113872667A (accessed 27.10.2024).

United States Patent № US 2008310742 A1, МПК G06V 10/25, G06V 10/40. Published 18.12.2018. Available at: https://worldwide.espacenet.com/

patent/search/family/040132399/publication/US2008310742A1?q= pn%3DUS2008310742A1 (accessed 27.10.2024).

Taiwan Patent № TW 202402056 A, МПК H 04 N 19/184; H 04 N 21/234. Published 01.01.2024. Available at: https://worldwide.espacenet.com/patent/ search/family/090457708/publication/TW202402056A?q=pn%3DTW202402056A (accessed 27.10.2024).

Bilozerskyi, V. O., Dergachov, K. Yu. and Кrasnov, L. O. Analiz i poperednya obrobka videodanykh dlya pidvyshchennya yakosti roboty system tekhnichnoho zoru [Tekst] [Analysis and pre-processing of video data to improve the quality of computer vision systems]. Problemy keruvannya ta informatyky – Problems of control and informatics, 2023, vol. 68, no. 2, pp. 50-66. DOI: 10.34229/1028-0979-2023-2-4. (In Ukrainian).

Bilozerskyi, V., Dergachov, K. and Кrasnov, L. New method for video stream brightness stabilization: algorithms and performance evaluation [Text]. Radioelektronni i komp'uterni sistemi – Radioelectronic and computer systems, 2023, no. 3, pp. 125-135. doi: 10.32620/reks.2023.3.10.

Egiazarian, K., Ponomarenko, M., Lukin, V. and Ieremeiev, O. Statistical Evaluation of Visual Quality Metrics for Image Denoising. 2018 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP), Calgary, AB, Canada, 2018, pp. 6752-6756. DOI: 10.1109/ICASSP.2018.8462294.

Lukin, V. V., Zriakhov, M. S., Ponomarenko, N. N., Krivenko, S. S. and Zhenjiang, M. Lossy compression of images without visible distortions and its application. IEEE 10th international conference on signal processing proceedings, Beijing, China, 2010, pp. 698-701. DOI: 10.1109/ICOSP.2010.5655751.

Raspberry Pi Foundation. Available at: https://www.raspberrypi.org/ (accessed 23.10.2024).

OpenCV Releases. Available at: https://opencv.org/releases/ (accessed 23.11.2024).

GStreamer. Open source multimedia framework. Available at: https://gstreamer.freedesktop.org/ (accessed 23.11.2024).

A. Bhat, I.E. Richardson and C. S. Kannangara. A Novel Perceptual Quality Metric for Video Compression. Proc. International Picture Coding Symposium 2009, Chicago, May 2009.