基于改进SE-Net和深度可分离残差的高光谱图像分类

兰州理工大学学报 ›› 2024, Vol. 50 ›› Issue (2): 87-95.

• 自动化技术与计算机技术 • 上一篇下一篇

基于改进SE-Net和深度可分离残差的高光谱图像分类

王燕^*, 王振宇

兰州理工大学计算机与通信学院, 甘肃兰州 730050

收稿日期:2022-03-04 出版日期:2024-04-28 发布日期:2024-04-29
通讯作者: 王燕(1971-),女,甘肃泾川人,教授.Email:wangyan@lut.edu.cn
基金资助:
国家自然科学基金(61863025),甘肃省重点研发计划-工业类(18YF1GA060)

Hyperspectral image classification based on improved SE-Net anddepth-separable residuals

WANG Yan, WANG Zhen-yu

College of Computer and Communication, Lanzhou Univ. of Tech., Lanzhou 730050, China

Received:2022-03-04 Online:2024-04-28 Published:2024-04-29

摘要/Abstract

摘要： 针对目前常见的用于高光谱图像分类的卷积神经网络参数数量多,训练时间长,对样本数量依赖性大的问题,提出一种适用于有限训练样本条件下基于改进压缩激活网络和深度可分离残差的分类网络MDSR&SE-Net.首先使用主成分分析对原始高光谱图像进行通道降维,然后通过三维卷积神经网络连接多特征残差结构,同时嵌入改进的SE模块提取高光谱图像的空间和光谱细节特征,最后将提取到的特征数据输入Softmax分类器激活分类.为了使网络更加轻量,通过在残差结构中使用深度可分离卷积和引入全局平均池化减少参数数量.实验结果显示,使用有限训练样本在三种常见高光谱数据集上总体分类精度均达到99%以上.

关键词: 高光谱图像, 深度可分离卷积, 残差网络, 压缩激活网络

Abstract: In response to the challenges posed by convolutional neural network (CNNs) commonly used for hyperspectral image classification, namely, their high parameter count, extended training times, and sensitivity to sample quantity, a classification network MDSR&SE-Net based on improved squeeze and excitation network and depth-separable residuals was proposed for limited training samples. First, the principal component analysis is employed in this model to reduce the dimension of the original HSI. Then, the multi-feature residual structure is connected by 3D convolutional neural network, and the spatial & spectral details of hyperspectral images are extracted by embedding the improved squeeze and excitation block. Finally, the extracted feature information is input into Softmax classifier to activate classification. To further lightweight the network, the number of parameters is reduced by using the depth separable convolution in the residual structure and introducing global average pooling. Experimental results show that overall accuracy of the three common hyperspectral data sets with the limited training samples are above 99%.

Key words: hyperspectral image, depth separable convolution, residual network, SE Net

中图分类号:

TP751.1

王燕, 王振宇. 基于改进SE-Net和深度可分离残差的高光谱图像分类[J]. 兰州理工大学学报, 2024, 50(2): 87-95.

WANG Yan, WANG Zhen-yu. Hyperspectral image classification based on improved SE-Net anddepth-separable residuals[J]. Journal of Lanzhou University of Technology, 2024, 50(2): 87-95.

参考文献

[1] MA H Q,HUANG W J,DONG Y Y,et al.Using UAV-based hyperspectral imagery to detect winter wheat fusarium head blight [J].Remote Sensing,2021,13(15):3024.
[2] NTURAMBIRWE J F,PEROLD W J,OPARA U L,et al.Classification learning of latent bruise damage to apples using shortwave infrared hyperspectral imaging [J].Sensors,2021,21(15):4990.
[3] YU R,REN L L,LUO Y Q,et al.Early detection of pine wilt disease in Pinus tabuliformis in North China using a field portable spectrometer and UAV-based hyperspectral imagery [J].Forest Ecosystems,2021,8(1):44.
[4] XIE W Y,ZHANG J Q,LEI J,et al.Self-spectral learning with GAN based spectral-spatial target detection for hyperspectral image [J].Neural Networks,2021,142:375-387.
[5] REZA S M,HASAN G.A probabilistic SVM approach for hyperspectral image classification using spectral and texture features [J].International Journal of Remote Sensing,2017,38(15):4265-4284.
[6] KOHEI A.Maximum likelihood classification based on classified result of boundary mixed pixels for high spatial resolution of satellite images [J].International Journal of Advanced Computer Science and Applications,2020,11(9):24-30.
[7] 颜铭靖,苏喜友.基于三维空洞卷积残差神经网络的高光谱影像分类方法 [J].光学学报,2020,40(16):163-172.
[8] JOHN R A,KANDASAMY J,VIGNESH T,et al.Development of computer vision for inspection of bolt using convolutional neural network [J].Materials Today: Proceedings,2021,45(7):6931-6935.
[9] LAKHAL M Y,CEVIKALP H,ESCALERA S.et al.Recurrent neural networks for remote sensing image classification [J].IET Computer Vision,2018,12(7):1040-1045.
[10] ATIF M,LIN M T.Multiple deep-belief-network based spectral-spatial classification of hyperspectral images [J].Tsinghua Science and Technology,2019,24(2):183-194.
[11] 康妙,计科峰,冷祥光,等.基于桟式自编码器特征融合的SAR图像车辆目标识别 [J].雷达学报,2017,6(2):167-176.
[12] 胡丽,单锐,王芳,等.基于双通道空洞卷积神经网络的高光谱图像分类 [J].激光与光电子学进展,2020,57(12):356-362.
[13] ROY S K,KRISHNA G,DUBEY S R,et al.HybridSN:exploring 3D-2D CNN feature hierarchy for hyper spectral image classification [J].IEEE Geoscience and Remote Sensing Letters,2020,17(2):277-281.
[14] ZHONG Z L,LI J,LUO Z M,et al.Spectral-spatial residual network for hyperspectral image classification:a 3-D deep learning framework [J].IEEE Transactions on Geoscience and Remote Sensing,2018,56(2):847-858.
[15] HU J,SHEN L,SUN G,et al.Squeeze-and-excitation networks [C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition.Los Alamitos:IEEE Computer Society Press,2018:7132-7141.
[16] HE K,ZHANG X,REN S,et al.Deep residual learning for image recognition [C]//IEEE Conference on Computer Vision and Pattern Recognition.Las Vegas:IEEE,2016:770-778.
[17] YUE J,ZHAO W Z,MAO S J,et al.Spectral-spatial classification of hyperspectral images using deep convolutional neural networks [J].Remote Sensing Letters,2015,6(6):468-477.
[18] CHEN S T,JIN M,DING J.Hyperspectral remote sensing image classification based on dense residual three-dimensional convolutional neural network [J].Multimedia Tools and Applications,2021,80(2):1859-1882.
[19] YAO W,LIAN C,BRUZZONE L.Cluster-CNN:clustering-based feature learning for hyperspectral image classification [J].IEEE Geoscience and Remote Sensing Letters,2021,18(11):1991-1995.
[20] LI L,YIN J H.Joint spatial-spectral attention network for hyperspectral image classification [J].IEEE Geoscience and Remote Sensing Letters,2021,18(10):1816-1820.

基于改进SE-Net和深度可分离残差的高光谱图像分类

Hyperspectral image classification based on improved SE-Net anddepth-separable residuals

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 1

编辑推荐

Metrics

本文评价