YOLO V3 AND CCN FOR THE TRACKING AND CLASSIFICATION OF AERIAL OBJECT AND DRONES

Zainab Mohanad Iss; Layla H. Abood; Dalal Abdulmohsin; Basim Galeb; Aqeel Al-Hilali

doi:10.26782/jmcms.2024.09.00006

Journal of Mechanics of Continua and Mathematical Sciences (Sep 2024)

YOLO V3 AND CCN FOR THE TRACKING AND CLASSIFICATION OF AERIAL OBJECT AND DRONES

Zainab Mohanad Iss,
Layla H. Abood,
Dalal Abdulmohsin,
Basim Galeb ,
Aqeel Al-Hilali

Affiliations

Zainab Mohanad Iss: Department of Computer, College of Computer Science and Information Technology, Wasit University, Iraq.
Layla H. Abood: Department of Control and Systems Engineering, University of Technology, Iraq.
Dalal Abdulmohsin: Department of Cybersecurity Technology Engineering, Middle Technical University, Iraq
Basim Galeb: Department of Computer Technician Engineering, Al Hikma University College, Iraq.
Aqeel Al-Hilali: Medical Instrumentation Engineering, Al-farahidi university, Iraq.

DOI: https://doi.org/10.26782/jmcms.2024.09.00006
Journal volume & issue: Vol. 19, no. 9
pp. 48 – 65

Abstract

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The goal of this study is to give headways in aeronautical article ID that will help with making recognitions that are both more exact and more precise. Specifically, we revamp the meaning of the article recognition anchor enclose request to remember turns for expansion to level and width, and besides, we make it conceivable to have erratic four corner point structures. Furthermore, the consideration of new anchor boxes gives the model additional adaptability to address protests that are focused at a pivot of turn that gives a 45-degree point. By accomplishing these results, we can make an organization that considers negligible tradeoffs about speed and unwavering quality, while likewise giving more exact restrictions. The latest ways to deal with PC vision and article acknowledgment are for the most part dependent on brain organizations and different advances that utilize profound learning. This powerful field of study is utilized in various applications, including military and observation, aeronautical photography, independent driving, and airborne perception. To precisely locate the location of an item, contemporary object identification techniques make use of bounding boxes that are drawn over the object and have a rectangular form (horizontal and vertical). These orthogonal bounding boxes do not consider the posture of the object, which leads to a decrease in the amount of object localization and restricts subsequent tasks such as object comprehension and tracking. We have used the DOTA dataset to present all of the results, demonstrating the value of flexible object boundaries, particularly with rotated and non-rectangular objects. We have also achieved an accuracy of 98.47% for the detection and classification of aerial objects, with forty percent of the data being used for training and the remaining twenty percent being used for testing. There was a minimum of 2.8 seconds of processing time required for the whole program to be executed to categorize all of the aerial items that were parked on the base.

Published in Journal of Mechanics of Continua and Mathematical Sciences

ISSN: 0973-8975 (Print); 2454-7190 (Online)
Publisher: Institute of Mechanics of Continua and Mathematical Sciences
Country of publisher: India
LCC subjects: Science: Mathematics
Website: https://www.journalimcms.org/

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