基于三阶段残差动态聚焦网络的羽绒图像分类

doi:10.13475/j.fzxb.20250800301

纺织学报 ›› 2026, Vol. 47 ›› Issue (02): 73-83.doi: 10.13475/j.fzxb.20250800301

基于三阶段残差动态聚焦网络的羽绒图像分类

吕泽彬¹, 李子印¹(), 汪小东², 叶飞², 刘伟红²

¹ 中国计量大学光学与电子科技学院, 浙江杭州 310018
² 湖州市质量技术监督检测研究院(湖州市纤维质量监测中心), 浙江湖州 313099

收稿日期:2025-08-04 修回日期:2025-11-06 出版日期:2026-02-15 发布日期:2026-04-24
通讯作者: 李子印(1978—),男,副教授,博士。主要研究方向为机器视觉。E-mail:liziyin@cjlu.edu.cn。
作者简介:吕泽彬(2001—),男,硕士生。主要研究方向为机器视觉。
基金资助:
浙江省市场监督管理局科技计划项目(ZC2025032)

Classification of down images based on tri-stage residual dynamic focusing network

LÜ Zebin¹, LI Ziyin¹(), WANG Xiaodong², YE Fei², LIU Weihong²

¹ College of Optical and Electronics Technology, China Jiliang University, Hangzhou, Zhejiang 310018, China
² Huzhou Institute of Quality and Technical Supervision and Inspection(Huzhou Fiber Quality Monitoring Center), Huzhou, Zhejiang 313099, China

Received:2025-08-04 Revised:2025-11-06 Published:2026-02-15 Online:2026-04-24

摘要/Abstract

摘要：

针对羽绒品质检测中的色泽、形态以及新鲜度等细粒度分类难题,提出了一种三阶段残差动态聚焦网络Tri-RDFNet,其核心骨架残差动态聚焦网络RDFNet以残差模型ResNet为主干网络,引入改进的卷积块注意力机制进行特征聚焦以及动态间隙关注损失函数对易混淆羽绒样本进行动态加权训练,同时在RDFNet的基础上引入预热训练、加权训练和样本精调训练3个不同阶段的级联训练策略,构成Tri-RDFNet网络模型,实现对复杂羽绒图像样本的高精度识别。通过采集白色新鲜绒、异色新鲜绒、白色回收绒与异色回收绒4种类型羽绒图像并进行数据增强操作,构建成8 000张羽绒图像数据集进行分类训练和测试。最终,模型在羽绒图像验证集上的结果显示,所提出的RDFNet网络在羽绒图像分类任务中取得95.28%的准确率,相比于目前经典的分类模型准确率至少提升1.11%,同时,引入三阶段级联训练策略的Tri-RDFNet模型,使得模型对于羽绒数据集的识别准确率进一步提升至97.01%,增强了模型的泛化能力,为羽绒品质检测提供了高效创新的解决方案。

关键词: 羽绒, 羽绒图像分类, 动态聚焦网络, 注意力机制, 动态间隙关注损失函数, 三阶段级联训练, 残差网络

Abstract:

Objective In down quality evaluation systems, key indicators such as color and freshness are decisive factors for product grading and market value. For fine-grained quality classification tasks involving down characteristics like color and freshness, traditional manual inspection methods exhibit low efficiency and strong subjectivity, while existing computational approaches demonstrate inadequate capability in recognizing the intricate texture patterns of down materials. To battle these challenges, this study proposes a Tri-phase residual dynamic focus network (Tri-RDFNet) to enhance the classification accuracy of down images, thereby advancing automated quality assessment in the down industry.

Method Building upon an enhanced ResNet architecture, a novel three-stage residual dynamic focus network was developed for fine-grained classification of down feather images. The network incorporated dilated convolution modules, deformable spatial-convolutional block attention module (DS-CBAM), and dynamic gap-aware attention loss (DGALoss) function to enable in-depth feature learning of down images. Furthermore, a three-stage cascaded training strategy was introduced to significantly improve the model's generalization capability. The experimental dataset, collected using industrial camera systems with a bar-shaped white light source, comprised four categories, i.e. white fresh down, white recycled down, colored fresh down, and colored recycled down. Comprehensive experiments were carried out using the established model.

Result Comparative experimental results demonstrated that traditional CNN models, such as AlexNet and VGG, exhibited certain performance bottlenecks in this task, achieving accuracy rates of only 89.32% and 90.26%, respectively. These models struggled to capture the fine-grained differences inherent in down feather images. Although Transformer-based models possess strong global modeling capabilities, they suffer from overfitting due to the limited dataset size and architectural complexity. The backbone model RDFNet enhanced the learning focus on down image features by incorporating atrous convolution modules, DS-CBAM, and DGALoss. As a result, it achieved a classification accuracy of 95.28% on the collected down image dataset, representing an improvement of 1.11%-5.96% compared to traditional models such as AlexNet, VGG, ResNet, ViT, and Swin Transformer. Furthermore, based on this RDFNet backbone, a three-stage cascaded training strategy was introduced. In the first stage, the model was trained globally using the cross-entropy loss function. The second stage employed DGALoss to reweight and train on easily confused samples, yielding a 1.02% increase in accuracy over the first stage. In the third stage, noise samples were filtered, and sample weights were reassigned to further train the retained samples. This final phase enhanced the model accuracy by an additional 0.71%, achieving a final accuracy of 97.01%. This three-stage process reduced the risk of overfitting while improving precision and generalization. Ablation studies confirmed the effectiveness of each component. The atrous convolution module improved the model's ability to perceive multi-scale features in down images, raising the validation accuracy by 0.99%. The DS-CBAM module enhanced the model's feature selection capability by integrating channel attention with deformable spatial convolution, leading to further improvement in accuracy while introducing minor overfitting. When combined, DS-CBAM and atrous convolution boosted accuracy to 95.28%. Introducing the three-stage training scheme and applying FocalLoss during the second stage to focus on hard examples increased accuracy to 96.11%, thus improving model robustness and stability. Replacing FocalLoss with DGALoss for better focus on confusing samples led to the highest validation accuracy of 97.01%, demonstrating DGALoss's superior capability in distinguishing ambiguous down categories.

Conclusion To address the challenge of fine-grained classification in down feather images, this paper proposes an innovative three-stage residual dynamic focusing network. The core backbone model, RDFNet, enhances feature extraction capabilities by improving the ResNet architecture through the integration of DS-CBAM and atrous convolution modules. Based on RDFNet, a three-stage training strategy is designed, consisting of warm-up training, adaptive weighted training using the novel DGALoss function, and refined sample training, collectively forming the Tri-RDFNet model. This approach effectively improves the recognition of easily confused down feather image samples and enhances the model's generalization ability. Experimental results demonstrate that the proposed method achieves a classification accuracy of 97.01% on a self-constructed dataset of 8 000 down feather images, significantly outperforming traditional methods. This provides an efficient solution for automated down quality assessment and offers a valuable reference for fine-grained image classification tasks.

Key words: down, down image classification, dynamic focusing network, attention mechanism, DGALoss, Tri-stage cascaded training, residual network

中图分类号:

TS107.2

吕泽彬, 李子印, 汪小东, 叶飞, 刘伟红. 基于三阶段残差动态聚焦网络的羽绒图像分类[J]. 纺织学报, 2026, 47(02): 73-83.

LÜ Zebin, LI Ziyin, WANG Xiaodong, YE Fei, LIU Weihong. Classification of down images based on tri-stage residual dynamic focusing network[J]. Journal of Textile Research, 2026, 47(02): 73-83.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250800301

http://www.fzxb.org.cn/CN/Y2026/V47/I02/73

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模型	准确率/%		参量M
模型	训练集	验证集	参量M
AlexNet	90.38	89.32	61
VGG19	92.26	90.26	143
ResNet18	92.09	91.78	11.7
ResNet24	93.16	92.06	12.36
ResNet50	93.67	92.56	25.6
Vision Transformer	95.81	93.77	≥86
Swin Transformer	95.38	94.17	≥29
RDFNet	95.69	95.28	23.3

模型结构组合	准确率/%
模型结构组合	训练集	验证集
ResNet24	93.16	92.06
ResNet24+空洞卷积	93.76	93.05
ResNet24+CBAM	94.33	93.09
ResNet24+DS-CBAM	95.09	93.56
ResNet24+空洞卷积+DS-CBAM (RDFNet)	95.69	95.28
Tri-RDFNet+FocalLoss	96.55	96.11
Tri-RDFNet+DGALoss	97.11	97.01

基于三阶段残差动态聚焦网络的羽绒图像分类

Classification of down images based on tri-stage residual dynamic focusing network

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