Object Detection and Segmentation Using Deeplabv3 Deep Neural Network for a Portable X-Ray Source Model-Reference-Cited by-同舟云学术

Object Detection and Segmentation Using Deeplabv3 Deep Neural Network for a Portable X-Ray Source Model

Published:2022-09-20 Issue:5 Volume:26 Page:842-850
ISSN:1883-8014
Container-title:Journal of Advanced Computational Intelligence and Intelligent Informatics
language:en
Short-container-title:JACIII

Author:

Rogelio Jayson P.,Dadios Elmer P.,Vicerra Ryan Ray P.,Bandala Argel A., , ,

Abstract

The primary purpose of this research is to implement Deeplabv3 architecture’s deep neural network in detecting and segmenting portable X-ray source model parts such as body, handle, and aperture in the same color scheme scenario. Similarly, the aperture is smaller with lower resolution making deep convolutional neural networks more difficult to segment. As the input feature map diminishes as the net progresses, information about the aperture or the object on a smaller scale may be lost. It recommends using Deeplabv3 architecture to overcome this issue, as it is successful for semantic segmentation. Based on the experiment conducted, the average precision of the body, handle, and aperture of the portable X-ray source model are 91.75%, 20.41%, and 6.25%, respectively. Moreover, it indicates that detecting the “body” part has the highest average precision. In contrast, the detection of the “aperture” part has the lowest average precision. Likewise, the study found that using Deeplabv3 deep neural network architecture, detection, and segmentation of the portable X-ray source model was successful but needed improvement to increase the overall mean AP of 39.47%.

Publisher

Fuji Technology Press Ltd.

Subject

Artificial Intelligence,Computer Vision and Pattern Recognition,Human-Computer Interaction

Reference58 articles.

1. J. Rogelio, E. Dadios, A. Bandala et al., “Alignment control using visual servoing and mobilenet single-shot multi-box detection (SSD): a review,” Int. J. of Advances in Intelligent Informatics, Vol.8, No.1, pp. 97-114, 2022.

2. Golden Engineering Inc., “Portable battery operated X-ray unit Golden Engineering XRS-4,” pp. 6-7.

3. J. P. Rogelio et al., “Modal Analysis, Computational Fluid Dynamics and Harmonic Response Analysis of a 3D Printed X-ray Film Handler for Assistant Robotic System Using Finite Element Method,” Proc. of the IEEE 12th Int. Conf. on Humanoid, Nanotechnology, Information Technology, Communication and Control, Environment and Management (HNICEM), doi: 10.1109/HNICEM51456.2020.9400014, 2020.

4. A. Kumar, Z. J. Zhang, and H. Lyu, “Object detection in real time based on improved single shot multi-box detector algorithm,” Eurasip J. on Wireless Communications and Networking, Vol.2020, No.1, Article No.204, 2020.

5. J. Liu and Y. Li, “Visual servoing with deep learning and data augmentation for robotic manipulation,” J. Adv. Comput. Intell. Intell. Inform., Vol.24, No.7, pp. 953-962, 2020.

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