基于轻量化网络和知识蒸馏的纱线状态检测

doi:10.13475/j.fzxb.20220508801

摘要/Abstract

摘要：

为准确识别导纱管内纱线数量与种类,保证纱线打结有序进行,提出一种基于卷积神经网络的纱线分类方法。首先,将采集到的3 500张图片分为训练集2 800张和测试集700 张,再从训练集中划出560张作为验证集;其次采用叠加深度可分离卷积构建轻量化的自搭建学生网络。为克服学生网络准确率低、泛化性能弱等缺陷,采用迁移学习与知识蒸馏的组合训练方式对自搭建网络进行训练,将最终训练得到的学生网络权重进行移动端部署应用。实验结果表明:在PC端上对自搭建学生网络采取组合训练方式有效,在移动端上单根纱线识别概率在70%以上、双根纱线为80%以且纱线检测平均准确率达98.86%。为针织行业有关纱线的检测与识别提供了新思路。

关键词: 纱线状态识别, 轻量化神经网络, 知识蒸馏, 迁移学习, 模型部署, 针织

Abstract:

Objective The knotting machine in the circular weft knitting production line absorbs the yarn at the end of different yarn cylinders through the yarn guide tube, and sends the absorbed yarn to the knotting device to complete the knotting process. Aiming at the problem that it is difficult to detect the multi-state and multi-type yarn absorption in the yarn guide tube of the splitter, a detection scheme based on machine vision was proposed to realize the real-time monitoring of yarn number and color in the yarn guide tube of the knot machine to ensure the reliability of the joint.

Method In order to overcome the limitation of convenional yarn detection, an image classification method based on deep learning was proposed. 3 500 collected images were divided into 2 800 training sets and 700 test sets, and 560 images were separated from the training set as the verification set. Following that, a lightweight self-built student network was constructed by using superposition depth separable convolution. In order to overcome the defects of low accuracy and weak generalization performance of students' network, the combination training method of transfer learning and knowledge distillation was utilized to train the self-built network, and the final trained student network weight was deployed on the mobile terminal.

Results Experimental results showed that the teacher network using transfer learning had a verification set accuracy of more than 92% after the first round, and the convergence speed of the loss curve was also significantly accelerated (Fig. 9). When the student network was trained by knowledge distillation, the setting of loss weight α and distillation temperature T had no rule on the verification accuracy of the network. Compared with the student network verification accuracy of 95.7% before distillation, it was improved in general (Tab. 3). When the loss weight α was set to 0.2 and the distillation temperature T was set to 3, the best effect was achieved, and the top-1 accuracy on the verification set reached 99.57%. Comparative experiments of model reasoning were conducted on student network, teacher network and typical lightweight network before and after distillation (Tab. 4). The accuracy of the student network, which was originally 96.00% accurate on the test set, was improved to 99.28% after distillation. In addition, compared with the current typical lightweight model, the self-built lightweight student network had fewer parameters and less computation, which indirectly improved the forward reasoning time of the model. When the trained self-built network was deployed on the embedded terminal for actual test, the probability of a single yarn was higher than 70% (Fig. 11), while the probability of a double yarn was higher than 80%. The actual yarn detection accuracy rate was 98.86% after repeated experimental test on the yarn (Tab. 5). The difference in test accuracy between PC and embedded terminal was observed. The analysis showed that the PC side test was in the form of pictures taken before, while the embedded side test was in the form of actual video stream. On the other hand, the precision of weight parameters may be lost during the process of model quantization acceleration and deployment.

Conclusion The analysis result shows that, on the one hand, the PC side test is in the form of pictures taken before, while the embedded side test is in the form of actual video stream. On the other hand, the precision of weight parameters may be lost during the process of model quantization acceleration and deployment. It can be seen from the above yarn testing results that it meets the practical application needs and lays a solid foundation for promoting the application and popularization of the later knotting machine. In addition, the current yarn detection device is suitable for the knotting machine, but only it is necessary to optimize and upgrade the hardware and algorithm, useful in many occasions relating to yarn detection. Its lightweight size and low cost are undoubtedly progressed with commercial promotion value and significance.

Key words: yarn recognition, lightweight neural network, knowledge distillation, transfer learning, deployment model, knitting

中图分类号:

TP391.41

任国栋, 屠佳佳, 李杨, 邱子安, 史伟民. 基于轻量化网络和知识蒸馏的纱线状态检测[J]. 纺织学报, 2023, 44(09): 205-212.

REN Guodong, TU Jiajia, LI Yang, QIU Zian, SHI Weiming. Yarn state detection based on lightweight network and knowledge distillation[J]. Journal of Textile Research, 2023, 44(09): 205-212.

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类型	卷积核尺寸/步长	输入尺寸
标准卷积	3×3/2	224×224×3
深度可分离卷积块	3×3/2,1×1	112×112×32
深度可分离卷积块	3×3/2,1×1	56×56×64
深度可分离卷积块	3×3/2,1×1	28×28×64
深度可分离卷积块	3×3/2,1×1	14×14×128
深度可分离卷积块	3×3,1×1	7×7×256
池化层	7×7	7×7×512
全连接层	512×7	1×1×512
Softmax	分类输出	1×1×7

参数名称	参数值
模型输入尺寸	224×224×3
交叉熵损失函数	Categorical_crossentropy
优化器	Adam
分类器	Softmax
迭代次数	100
批大小	32
学习率	0.000 1

T	验证集Top-1准确率/%
T	α=0.1	α=0.2	α=0.3	α=0.4
1	99.04	99.21	99.21	97.96
3	99.21	99.57	97.61	98.68
5	97.72	97.61	99.21	99.57
7	98.68	97.96	99.04	97.96
10	99.04	99.21	99.39	97.68

模型	准确率/ %	参数量 10⁶	运算量 10⁶	内存大小/ MB	时间/ms
模型	准确率/ %	参数量 10⁶	运算量 10⁶	内存大小/ MB	CPU	GPU
老师网络 (ResNet34)	99.89	21.29	3 670	37.61	63.99	7.46
学生网络	96.00	0.19	34.44	10.12	8.11	1.73
KD+学生网络	99.28	0.19	34.44	10.12	8.12	1.77
MobileNet_ V3_Small	99.16	1.53	58.80	50.39	22.07	7.33
ShuffleNet_ V2_x0.5	99.27	1.37	43.65	11.24	26.97	9.35

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