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《南京师大学报（自然科学版）》[ISSN:1001-4616/CN:32-1239/N]

Issue:

2018年04期

Page:

79-

Research Field:

·数学与计算机科学·

Publishing date:

Info

Title:

Airplane Detection in Remote Sensing ImageBased on Faster-RCNN Algorithm

Author(s):

Zhang Zhongbao; Wang Hongyuan; Zhang Ji; Yang Wei

School of Information Science and Engineering,Changzhou University,Changzhou 213164,China

Keywords:

remote sensing images; airplane detection; Faster-RCNN; residual network; region proposal network; online hard example mining

PACS:

TP391

DOI:

10.3969/j.issn.1001-4616.2018.04.013

Abstract:

CCCV2017 releases remote sensing image airplane dataset for evaluating airplane detection algorithm. Due to the uncertainty of the orientation of airplanes in remote sensing images and the images with a wide coverage and high background complexity,airplane detection is difficult,the precision and the generalization ability of the model are low. This paper proposes an improved airplane detection algorithm based on Faster-RCNN. First of all,the dataset is reasonably augmented by flipping and rotating the images; then,on the augmented dataset,the residual network is used to extract features from the images and the region proposal network is optimized based on the characteristics of the aspect ratio of airplanes; at the same time,in order to prevent imbalance between positive and negative samples in the training set,the online hard example mining method is used to train the data. The evaluation on the CCCV2017 dataset shows that the improved Faster-RCNN algorithm greatly improved the performance of the initial Faster-RCNN algorithm. In the test set,the mAP(mean Average Precision,mAP)has reached 89.93%. Tests on NWPU VHR-10,NWPU VHR-45,and UCAS-AOD remote sensing image datasets show that the improved model also has good performance,which verifies that the model has good robustness and generalization ability.

References:

[1] 尹宏鹏,陈波,柴毅,等. 基于视觉的目标检测与跟踪综述[J]. 自动化学报,2016,42(10):1466-1489.
[2]LOWE D G. Distinctive image features from scale-invariant keypoints[J]. International journal of computer vision,2004,60(2):91-110.
[3]DALAL N,TRIGGS B. Histograms of oriented gradients for human detection[C]//Proceedings of the IEEE Computer Society Conference on Computer Vision & Pattern Recognition. San Diego,2005,1(12):886-893.
[4]MALLAT S. A wavelet tour of signal processing[M]. Beijing:China Machine Press,2010.
[5]VAPNIK V,CORTES C. Support vector networks[J]. Machine learning,1995,20(3):273-297.
[6]CHENG J,GREINER R. Comparing bayesian network classifiers[J]. IEEE transactions on vehicular technology,2013,63(5):2002-2012.
[7]LECUN Y,BOTTOU L,BENGIO Y,et al. Gradient-based learning applied to document recognition[J]. Proceedings of the IEEE,1998,86(11):2278-2324.
[8]UIJLINGS J R,SANDE K E,GEVERS T,et al. Selective search for object recognition[J]. International journal of computer vision,2013,104(2):154-171.
[9]GIRSHICK R,DONAHUE J,DARRELL T. Rich feature hierarchies for accurate object detection and semantic segmentation[C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Columbus,2014:580-587.
[10]GIRSHICK R. Fast R-CNN[DB/OL]. [2018-10-22]. https://arxiv.org/pdf/1504.08083.pdf.
[11]REN S Q,HE K M,GIRSHICK R,et al. Faster R-CNN:towards real-time object detection with region proposal networks[J]. IEEE transactions on pattern analysis & machine intelligence,2017,39(6):1137-1149.
[12]REDMON J,DIVVALA S,GIRSHICK R,et al. You only look once:unified,real-time object detection[C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Las Vegas,2016:779-788.
[13]HE K M,ZHANG X Y,REN S Q,et al. Deep residual learning for image recognition[C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Las Vegas,2016:770-778.
[14]SHRIVASTAVA A,GUPTA A,GIRSHICK R. Training region-based object detectors with online hard example mining[C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Las Vegas,2016:761-769.
[15]DAI J,LI Y,HE K,et al. R-FCN:object detection via region-based fully convolutional networks[DB/OL]. [2018-10-22]. https://arxiv.org/pdf/1605.06409.pdf.
[16]ZEILER M D,FERGUS R. Visualizing and understanding convolutional networks[DB/OL]. [2018-10-22]. https://arxiv.org/pdf/1311.2901.pdf.
[17]SIMONYAN K,ZISSERMAN A. Very deep convolutional networks for large-scale image recognition[DB/OL]. [2018-10-22]. https://arxiv.org/pdf/1409.1556.pdf.
[18]CHENG G,HAN J W,ZHOU P C,et al. Multi-class geospatial object detection and geographic image classification based on collection of part detectors[J]. Isprs journal of photogrammetry & remote sensing,2014,98(1):119-132.
[19]CHENG G,HAN J W. A survey on object detection in optical remote sensing images[J]. Isprs journal of photogrammetry & remote sensing,2016,117:11-28.
[20]CHENG G,ZHOU P C,HAN J W. Learning rotation-invariant convolutional neural networks for object detection in VHR optical remote sensing images[J]. IEEE transactions on geoscience & remote sensing,2016,54(12):7405-7415.
[21]CHENG G,HAN J W,LU X Q. Remote sensing image scene classification:benchmark and state of the art[J]. Proceedings of the IEEE,2017,105(10):1865-1883.
[22]ZHU H G,CHEN X G,DAI W Q,et al. Orientation robust object detection in aerial images using deep convolutional neural network[C]//Proceedings of the IEEE International Conference on Image Processing. Quebec,2015:3735-3739.

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Last Update: 2018-12-30