Algorithm for Forming a Computer Vision Model in the Interests of an Air Reconnaissance System
DOI:
https://doi.org/10.31649/1997-9266-2025-180-3-140-146Keywords:
unmanned aerial vehicle, air reconnaissance, object of interest, digital image, efficiency, reliability, artificial intelligence, computer visionAbstract
The significant growth of data traffic generated using unmanned aircraft systems and transmitted to the command and control station has increased the requirements for collecting and processing of aerial reconnaissance data. Main requirements include the efficiency of processing aerial monitoring data and the reliability of aerial reconnaissance data. In this regard, the issue of integrating the computer vision and artificial intelligence technologies into the process of processing intelligence information is relevant. Requirements are formed for a computer vision model in the interests of the aerial reconnaissance system, the main ones are the following: provision of automated detection and classification of objects of interest in digital images (video frames); provision of the required level of efficiency of aerial reconnaissance data processing; guaranteeing the possibility of transforming the computer vision model; ensuring the necessary level of reliability of aerial reconnaissance data in the conditions of using UAVs; taking into account the professional competencies of specialists in collecting and processing intelligence information; simplicity of algorithmic implementation; efficiency of model formation.
The algorithm for the formation of a computer vision model is developed in the interest of the air reconnaissance system to increase the efficiency of processing air monitoring data in the conditions of providing the required level of reliability. A distinctive feature of the proposed algorithm is considering the level of operator training and computing power of the unmanned aviation complex (command and control station) to form a computer vision model. This allows to choose one of two approaches to training the model (autonomous, using the resources of open web platforms), which, in turn, allows to create conditions for increasing the efficiency of processing air monitoring data in the conditions pf providing l the required level of reliability. Further scientific research will be directed for the assessment of the the effectiveness of using the proposed approach to increase the autonomy of unmanned aviation systems in the interests of the air reconnaissance system.
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