Ship Detection in SAR Images Based on Multiscale Feature Fusion and Channel Relation Calibration of Features

Ship Detection in SAR Images Based on Multiscale Feature Fusion and Channel Relation Calibration of Features

Deep-learning technology has enabled remarkable results for ship detection in SAR images. However, in view of the complex and changeable backgrounds of SAR ship images, how to accurately and efficiently extract target features and improve detection accuracy and speed is still a huge challenge. To so...

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Bibliographic Details
Published in:Journal of radars = Lei da xue bao Vol. 10; no. 4; pp. 531 - 543
Main Authors: Xueke ZHOU, Chang LIU, Bin ZHOU
Format: Journal Article
Language:English
Published: China Science Publishing & Media Ltd. (CSPM) 01-08-2021
Subjects:
channel attention
faster r-cnn
features fusion
sar
ship detection
Online Access:Get full text
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Summary:Deep-learning technology has enabled remarkable results for ship detection in SAR images. However, in view of the complex and changeable backgrounds of SAR ship images, how to accurately and efficiently extract target features and improve detection accuracy and speed is still a huge challenge. To solve this problem, a ship detection algorithm based on multiscale feature fusion and channel relation calibration of features is proposed in this paper. First, based on Faster R-CNN, a channel attention mechanism is introduced to calibrate the channel relationship between features in the feature extraction network, so as to improve the network’s expression ability for extraction of ship features in different scenes. Second, unlike the original method of generating candidate regions based on single-scale features, this paper introduces an improved feature pyramid structure based on a neural architecture search algorithm, which helps improve the performance of the network. The multiscale features are effectively fused to settle the problem of missing detections of small targets and adjacent inshore targets. Experimental results on the SSDD dataset show that, compared with the original Faster R-CNN, the proposed algorithm improves detection accuracy from 85.4% to 89.4% and the detection rate from 2.8 FPS to 10.7 FPS. Thus, this method effectively achieves high-speed and high-accuracy SAR ship detection, which has practical benefits.
ISSN:2095-283X
DOI:10.12000/JR21021