THE METHOD FOR OBJECTS DETECTION ON SATELLITE IMAGERY BASED ON THE FIREFLY ALGORITHM
Main Article Content
Abstract
The subject matter of the article is the method for detecting of objects on satellite imagery based on the firefly algorithm. The goal is to develop a method for detecting of objects on satellite imagery based on the firefly algorithm. The tasks are: analysis of existing methods for detecting of objects of interest on satellite imagery, development of a method for detecting of objects on satellite imagery, practical verification of the method for detecting of objects on satellite imagery based on the firefly algorithm, and quantitative assessment of the quality of the proposed method. The methods used are: methods of digital image processing, methods of data clustering, mathematical apparatus of matrix theory, methods of swarm intelligence, methods of mathematical modeling, methods of optimization theory, analytical and empirical methods of image comparison. The following results are obtained. The advantages and disadvantages of the main methods and approaches to the processing of satellite imagery for the purpose of detecting objects of interest on them are determined. The general principle of operation of the firefly algorithm is considered. It presents a flowchart of the method for detecting of objects on satellite imagery based on the firefly algorithm in one color channel. The values of the input data and parameters for the operation of the algorithm were selected experimentally. Experimental studies were conducted on the operation of the method for detecting of objects on a real satellite imagery based on the firefly algorithm. The values of the errors of the first and second kind for the processed image using the proposed method and the method based on the particle swarm algorithm were calculated. Conclusions. Analysis of the calculated values showed that the proposed method for detecting of objects on satellite imagery compared to the method based on the particle swarm algorithm: reduces the error of the first kind by about 11% and the error of the second kind by about 9%. The directions of further research are the study of the problem of selecting input parameters and data for the operation of the method based on the firefly algorithm.
Article Details
References
Honchar, Ia. (2023), How the Delta Troop Management System Works, available at: https://mil.in.ua/uk/articles/yak-pratsyuye-systema-upravlinnya-vijskamy-delta-interv-yu-zi-spivzasnovnykom-go-aerorozvidka-yaroslavom-goncharom/
Munir, A., Aved, A. and Blasch, E. (2022), “Situational Awareness: Techniques, Challenges, and Prospects”, AI, vol. 3 (1), pp. 55–77, doi: https://doi.org/10.3390/ai3010005
Fedorov M. (2023), Ukraine presented its situational awareness system at the NATO Tide Sprint event, We are Ukraine, available at: https://www.weareukraine.info/ukraine-presented-its-situational-awareness-system-at-the-nato-tide-sprint-event/
Khizhnyak, І. (2019), “Applied Information Technology of Thematic Segmentation of Optical-Electronic Images from On-board Systems of Remote Sensing of the Earth”, Advanced Information Systems, vol. 3, no. 2, pp. 40–46, doi: https://doi.org/10.20998/2522-9052.2019.2.07
Al-Azawi, R. J., Al-Jubouri, Q. S. and Mohammed, Y. A. (2019), “Enhanced Algorithm of Superpixel Segmentation Using Simple Linear Iterative Clustering”, IEEE 12th International Conference on Developments in eSystems Engineering (DeSE), vol. 19568614, doi: https://doi.org/10.1109/DeSE.2019.00038
Pestunov, I. A., Rylov, S. A. and Berikov V. B. (2015), “Hierarchical clustering algorithms for segmentation of multispectral images”, Optoelectronics Instrumentation and Data Processing, vol. 50 (4), pp. 329–338, doi: https://doi.org/10.3103/S8756699015040020
Pesaresi, M. and Benediktsson, J. A. (2001), “A new approach for the morphological segmentation of high-resolution satellite imagery”, IEEE Transactions on Geoscience and Remote Sensing, vol. 39 (2), pp. 309–320, doi: https://doi.org/10.1109/36.905239
Avenash, R. and Viswanath, P. (2019), “Semantic Segmentation of Satellite Images using a Modified CNN with Hard-Swish Activation Function”, 14th International Joint Conference on Computer Vision, Imaging and Computer Graphics Theory and Applications (VISIGRAPP), pp. 413–420, doi: https://doi.org/10.5220/0007469604130420
Neupane, B., Horanont, Т. and Aryal, J. (2021), “Deep Learning-Based Semantic Segmentation of Urban Features in Satellite Images: A Review and Meta-Analysis”, Remote Sensing, vol. 13(4), 808, doi: https://doi.org/10.3390/rs13040808
Long, J., Shelhamer, E. and Darrell, T. (2015), “Fully convolutional networks for semantic segmentation”, IEEE Conference on Computer Vision and Pattern Recognition, pp. 3431–3440, doi: https://doi.org/10.1109/CVPR.2015.7298965
Lopez, J., Branch, J. W. and Chen, G. (2019), “Line-based image segmentation method: a new approach to segment VHSR remote sensing images automatically”, European Journal of Remote Sensing, vol. 52 (1), pp. 613–631, doi: https://doi.org/10.1080/22797254.2019.1699449
Xue, Y., Zhao, J. and Zhang, M. (2021), “A Watershed-Segmentation-Based Improved Algorithm for Extracting Cultivated Land Boundaries”, Remote Sensing, vol. 13 (939), doi: https://doi.org/ 10.3390/rs13050939
Safarov, F., Temurbek, K., Jamoljon, D., Temur, O., Chedjou, J. C., Abdusalomov, A. B. and Cho, Y. I. (2022), “Improved Agricultural Field Segmentation in Satellite Imagery Using TL-ResUNet Architecture”, Sensors, vol. 22 (24), 9784, doi: https://doi.org/10.3390/s22249784
Meeboonmak, N. and Cooharojananone, N. (2020), “Aircraft Segmentation from Remote Sensing Images using Modified Deeply Supervised Salient Object Detection with Short Connections”, IEEE International Conference on Mathematics and Computers in Science and Engineering (MACISE), 20504366, doi: https://doi.org/10.1109/MACISE49704.2020.00040
Hassanien, E. and Emary, E. (2016), “Swarm Intelligence Principles, Advances, and Applications”, CRC Press, 220 p., doi: https://doi.org/10.1201/9781315222455
Ruban, I., Khudov, H., Makoveichuk, O., Khizhnyak, I., Lukova-Chuiko, N., Pevtsov, G., Sheviakov, Y., Yuzova, I., Drob, Y. and Tytarenko, O. (2019), “Method for Determining Elements of Urban Infrastructure Objects Based on the Results from Air Monitoring”, Eastern-European Journal of Enterprise Technologies, № 4/9 (100), pp. 52–61, doi: https://doi.org/10.15587/1729-4061.2019.174576
Chen, K., Zhou, Y., Zhang, Z., Dai, M., Chao, Y. and Shi J. (2016), “Multilevel Image Segmentation Based on an Improved Firefly Algorithm”, Mathematical Problems in Engineering, pp. 1–12. doi: https://doi.org/10.1155/2016/1578056
Hema C., Sankar S. and Sandhya. (2017), “Performance comparison of dragonfly and firefly algorithm in the RFID network to improve the data transmission”, Journal of Theoretical and Applied Information Technology, vol. 95 (1), pp. 59–67, available at: https://www.jatit.org/volumes/Vol95No1/7Vol95No1.pdf
(2023), “WorldView-2 Satellite Image Gallery Satellite”, Imaging Corporation, available at: https://www.satimagingcorp.com/gallery/worldview-2/
Khudov, H., Makoveichuk, O., Khizhnyak, I., Glukhov, S.,, Shamrai, N., Rudnichenko, S., Husak, M. and Khudov, R, (2022), “The Choice of Quality Indicator for the Image Segmentation Evaluation”, International Journal of Emerging Technology and Advanced Engineering, No. 12 (10), pp. 95–103, doi: https://doi.org/10.46338/ijetae1022_11
Khudov, H., Makoveichuk, O., Khizhnyak, I., Oleksenko, O., Khazhanets, Y., Solomonenko, Y., Yuzova, I., Dudar, Y., Stetsiv, S. and Khudov, V. (2022), “Devising a Method for Segmenting Complex Structured Images Acquired from Space Observation Systems Based on the Particle Swarm Algorithm”, Eastern-European Journal of Enterprise Technologies, No. 2 /9 (116), pp. 6–13, doi: https://doi.org/10.15587/1729-4061.2022.255203