Automatic Target Detection from Satellite Imagery Using Machine Learning

doi:10.3390/s22031147

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Automatic Target Detection from Satellite Imagery Using Machine Learning

Tahir, A, Munawar, HS, Akram, J, Adil, M, Ali, S, Kouzani, Abbas and Mahmud, M A Parvez 2022, Automatic Target Detection from Satellite Imagery Using Machine Learning, Sensors, vol. 22, no. 3, pp. 1-22, doi: 10.3390/s22031147.

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Title	Automatic Target Detection from Satellite Imagery Using Machine Learning
Author(s)	Tahir, A Munawar, HS Akram, J Adil, M Ali, S Kouzani, Abbas orcid.org/0000-0002-6292-1214 Mahmud, M A Parvez orcid.org/0000-0002-1905-6800
Journal name	Sensors
Volume number	22
Issue number	3
Start page	1
End page	22
Total pages	22
Publisher	MDPI
Place of publication	Basel, Switzerland
Publication date	2022
ISSN	1424-8220 1424-8220
Keyword(s)	Science & Technology Physical Sciences Technology Chemistry, Analytical Engineering, Electrical & Electronic Instruments & Instrumentation Chemistry Engineering deep learning satellite images YOLO faster RCNN SSD SIMRDWN WIRELESS SENSOR NETWORKS COVERAGE ALGORITHM LIFETIME
Summary	Object detection is a vital step in satellite imagery-based computer vision applications such as precision agriculture, urban planning and defense applications. In satellite imagery, object detection is a very complicated task due to various reasons including low pixel resolution of objects and detection of small objects in the large scale (a single satellite image taken by Digital Globe com-prises over 240 million pixels) satellite images. Object detection in satellite images has many challenges such as class variations, multiple objects pose, high variance in object size, illumination and a dense background. This study aims to compare the performance of existing deep learning algorithms for object detection in satellite imagery. We created the dataset of satellite imagery to perform object detection using convolutional neural network-based frameworks such as faster RCNN (faster region-based convolutional neural network), YOLO (you only look once), SSD (single-shot detector) and SIMRDWN (satellite imagery multiscale rapid detection with windowed networks). In addition to that, we also performed an analysis of these approaches in terms of accuracy and speed using the developed dataset of satellite imagery. The results showed that SIMRDWN has an accuracy of 97% on high-resolution images, while Faster RCNN has an accuracy of 95.31% on the standard resolution (1000 × 600). YOLOv3 has an accuracy of 94.20% on standard resolution (416 416) while on the other hand SSD has an accuracy of 84.61% on standard resolution (300 × 300). When it comes to speed and efficiency, YOLO is the obvious leader. In real-time surveillance, SIMRDWN fails. When YOLO takes 170 to 190 milliseconds to perform a task, SIMRDWN takes 5 to 103 milliseconds.
Language	eng
DOI	10.3390/s22031147
Field of Research	0301 Analytical Chemistry 0502 Environmental Science and Management 0602 Ecology 0805 Distributed Computing 0906 Electrical and Electronic Engineering
HERDC Research category	C1 Refereed article in a scholarly journal
Free to Read?	Yes
Persistent URL	http://hdl.handle.net/10536/DRO/DU:30162522

Document type:	Journal Article
Collections:	Faculty of Science, Engineering and Built Environment School of Engineering Open Access Collection

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Created:	Tue, 15 Feb 2022, 13:17:47 EST