基于CNN的木材内部CT图像缺陷辨识

doi:10.11707/j.1001-7488.20181118

摘要/Abstract

摘要： [目的]为获取木材内部构造形态，提高木材内部缺陷识别率，依据获得的计算机断层扫描图像，提出一种基于卷积神经网络（CNN）的木材内部缺陷辨识方法，以实现木材的高效化自动分类。[方法]首先，利用课题组自行开发的计算机断层扫描系统，采集样本木材内部CT图像800幅；然后，对样本图像进行处理，随机选取700幅原始样本图像，从中截取出单个缺陷区域和正常木材断层区域样本图像20 000幅，并利用图像增强等算法将数据集扩充到70 000幅，标准化图像大小为28×28像素，分为正常、裂纹、虫眼和节子图像共4类，取60 000幅图像作为训练集，10 000幅图像作为测试集，剩余的100幅原始样本图像用于试验验证。[结果]通过60 000幅图像来训练网络模型，对测试集10 000幅图像进行分类，分类正确率达99.3%；利用训练得到的网络模型对100幅原始样本图像进行验证，平均分类正确率为95.87%。[结论]基于卷积神经网络的木材内部CT图像缺陷辨识算法，克服了传统识别方法图像预处理繁琐、训练方法复杂、训练参数过多、耗时过多等问题，具有精度高、复杂度小、鲁棒性较好等优点，且辨识正确率和辨识时间都比现行常规算法精准并用时短，是一种无损、高效、准确的辨识分类方法。

关键词: 木材, 无损检测, 卷积神经网络, 图像辨识

Abstract: [Objective] In order to obtain the internal structure form of wood and improve the identification rate of internal defects in wood,according to the computed tomography image,a method of identification and classification of wood interior defects based on convolution neural network algorithm is proposed,which realizes the automatic classification of wood efficiently.[Method] First of all, the internal cross-sectional CT images of wood samples on independent design were obtained, and the computed tomography system equipment was developed. Then,700 original sample images are randomly select after processed these sample images,from which 20 000 sample images of single defect region can be intercepted. The data set is expanded to 70 000 images by image enhancement algorithm. The size of normalized image is 28×28 pixel,and it can be divided into four parts:normal,cracked,insect hole and knot,from which 60 000 pictures of them are taken as training set,and the remaining 10 000 pictures are taken as test set. The remaining 100 images are used to implement doing experimental test.[Result] 60 000 sample images are used to train the network model,and the 10 000 sample images are classified. The classification accuracy is up to 99.3%. The accuracy of the average classification is 95.87% by verifying the remaining 100 original sample data.[Conclusion] The classification method that based on convolution neural network algorithm overcomes the problem of complicated image preprocessing,complex training method,numerous training parameters and amounts of time consuming and so on. It has the advantages of high precision,low complexity and good robustness. The identification accuracy and time are more accurate and shorter than those of the current conventional algorithms. It is a non-destructive,efficient and accurate classification method.

Key words: wood, nondestructive testing, convolution neural network, image identification

中图分类号:

陈龙现, 葛浙东, 罗瑞, 刘传泽, 刘晓平, 周玉成. 基于CNN的木材内部CT图像缺陷辨识[J]. 林业科学, 2018, 54(11): 127-133.

Chen Longxian, Ge Zhedong, Luo Rui, Liu Chuanze, Liu Xiaoping, Zhou Yucheng. Identification of CT Image Defects in Wood Based on Convolution Neural Network[J]. Scientia Silvae Sinicae, 2018, 54(11): 127-133.

参考文献

陈耀丹,王连明. 2016. 基于卷积神经网络的人脸识别方法.东北师大学报:自然科学版,48(2):70-76.
(Chen Y D,Wang L M. 2016. Convolutional neural network for face recognition method. Journal of Northeast Normal University:Natural Science Edition, 48(2):70-76.[in Chinese])
傅隆生,冯亚利,Elkamil T,等. 2018. 基于卷积神经网络的田间多簇猕猴桃图像识别方法.农业工程学报, 34(2):205-211.
(Fu L S, Wen Y L, Elkamil T, et al. 2018. Image recognition method of multi-cluster kiwifruit in field based on convolutional neural networks. Transactions of the Chinese Society of Agricultural Engineering, 34(2):205-211.[in Chinese])
葛浙东,侯晓鹏,鲁守银,等. 2016. 基于反投影坐标快速算法的木材CT检测系统研究.农业机械学报,47(3):335-341.
(Ge Z D,Hou X P,Lu S Y,et al. 2016. Wood CT detection system based on fast algorithm of inverse projection coordinate. Transactions of the Chinese Society of Agricultural Machinery,47(3):335-341,327.[in Chinese])
马旭,刘应安,业宁,等. 2017. 基于核PCA与SVM算法的木材缺陷识别. 常州大学学报:自然科学版,29(3):60-68.
(Ma X,Liu Y A,Ye N,et al.2017.Application of KPCA and SVM to wood defect recognition. Journal of Changzhou University:Natural Science Edition,29(3):60-68.[in Chinese])
牟洪波. 2006. 基于人工神经网络的木材缺陷检测研究. 哈尔滨:东北林业大学硕士学位论文.
(Mou H B. 2006. Study on wood defects testing base on artificial neural network. Harbin:MS thesis of Northeast Forestry University.[in Chinese])
黎奉薪. 2016. 基于深层卷积神经网络的物体识别研究. 哈尔滨:哈尔滨工业大学硕士学位论文.
(Li F X. 2016. Research on object recognition based on deep convolution neural network. Harbin:MS thesis of Harbin Institute of Technology.[in Chinese])
李思泉,张轩雄. 2018. 基于卷积神经网络的人脸表情识别研究.软件导刊,17(1):28-31.
(Li S Q,Zhang X X. 2018. Study on face expression recognition based on convolutional neural network. Software Guide,17(1):28-31.[in Chinese])
刘璐璐. 2017. 基于卷积神经网络的人体行为识别研究. 北京:中国科学技术大学硕士学位论文.
(Liu L L. 2017. Research on human body action recognitiom by convolutional neural networks. Beijing:MS thesis of Univercity of Science and Technology of China.[in Chinese])
戚大伟,牟洪波. 2013. 基于Hu不变矩和BP神经网络的木材缺陷检测.东南大学学报:自然科学版,43(s1):63-66.
(Qi D W,Mou H B.2013. Detection of wood defects types based on Hu invariant moments and BP neural network. Journal of Southeast University:Natural Science Edition,43(s1):63-66.[in Chinese])
王再超,李光辉,冯海林,等. 2015. 基于应力波和支持向量机的木材缺陷识别分类方法.南京林业大学学报:自然科学版,39(3):130-136.
(Wang Z C,Li G H,Feng H L,et al. 2015. A method of wood defect identification and classification based on stress wave and SVM. Journal of Nanjing Forestry University:Natural Science Edition,39(3):130-136.[in Chinese])
杨洋,申世杰. 2010.木材无损检测技术研究历史、现状和展望.科技导报,28(14):113-117.
(Yang Y,Shen S J. 2010. History,present state and future of non-destructive testing for wood. Science & Technology Review,28(14):113-117.[in Chinese])
张红,马静. 2017. 基于卷积神经网络的手写数字识别算法.电子技术与软件工程,(22):176.
(Zhang H,Ma J. 2017. Handwritten numeral recognition algorithm based on convolutional neural networks. Electronic Technology & Software Engineering,(22):176.[in Chinese])
张甜,程小武,陆伟东,等. 2016 超声波法检测木材内部孔洞缺陷的研究.西南林业大学学报,36(1):121-125.
(Zhang T,Cheng X W,Lu W D,et al. 2016. Experimental study on testing internal hole defects of wood by ultrasonic method. Journal of Southwest Forestry University,36(1):121-125.[in Chinese])
Alwzwazy H,Albehadili H,Alwan Y,et al. 2016. Handwritten digit recognition using convolutional neural networks. International Journal of Innovative Research in Computer & Communication Engineering,4(2):1101-1106.
Dobhal T,Shitole V,Thomas G,et al. 2015. Human activity recognition using binary motion image and deep learning. Procedia Computer Science,58:178-185.
Ronao C A,Cho S B. 2016. Human activity recognition with smartphone sensors using deep learning neural networks. Expert Systems with Applications,59:235-244.
Singh R,Om H. 2017. Newborn face recognition using deep convolutional neural network. Multimedia Tools & Applications,76(18):19005-19015.
Yang W,Jin L,Tao D,et al. 2016. Dropsample:a new training method to enhance deep convolutional neural networks for large-scale unconstrained handwritten Chinese character recognition. Pattern Recognition,58(4):190-203.

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