A Vehicle Re-identification Method Based on Feature Interaction and Multi-modal Adaptive Fusion
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摘要: 针对可见光传感器弱光照条件下分辨率受限及单一模态表征不足导致的车辆再识别准确率低的问题,研究了基于特征动态交互和多模态自适应融合的车辆再识别方法。在网络结构方面,将SimAM模块嵌入到YOLOv9模型的骨干网络卷积层,在不引入额外参数的前提下,对不同模态特征间的空间与通道关系进行建模,提取可见光、近红外、远红外模态的初始特征。构建多模态特征交互模块,对3种模态进行特征精细提取并进行模态间信息的交互聚合,提取3种模态的增强特征。搭建多模态自适应特征融合网络,通过提取3种模态的全局向量和掩膜向量,动态自适应生成相应模态的权重系数,进而实现多模态的特征融合。针对样本类内差异大、类间差异小、及同一车辆在不同场景下显著变化的特点,构造交叉熵损失、对比损失和中心损失等多重损失函数,实现多模态的车辆再识别。为验证所提方法的有效性,在多模态数据集RGBN300和RGBNT100上开展实验验证,并与主流方法进行对比分析。针对RGBN300数据集,mAP提升了20.6%、29.0%、5.0%和3.5%;针对RGBNT100数据集,mAP提升了22.5%、12.0%、3.7%和3.0%,Rank-1、Rank-5和Rank-10达到了95.1%、96.7%和96.9%。实验结果表明:通过特征交互和多模态自适应融合,所提取的融合特征更具判别性,车辆再识别性能得到了有效提升。Abstract: The limited resolution of visible-light sensors under weak illumination conditions and the insufficient representational capacity of a single modality lead to low vehicle re-identification accuracy. To address this problem, a vehicle re-identification method based on dynamic feature interaction and adaptive multi-modal fusion is proposed. In terms of network architecture, the SimAM module is embedded into the convolutional layers of the YOLOv9 backbone network without introducing additional parameters, enabling the modeling of spatial and channel relationships within features and extracting initial representations from visible, near-infrared, and far-infrared modalities. A multi-modal feature interaction module is then constructed to perform refined feature extraction and cross-modal information exchange, thereby obtaining enhanced features for all three modalities. Furthermore, a multi-modal adaptive feature fusion network is designed, in which the weighting coefficients for each modality are adaptively generated based on global vectors and mask vectors, achieving effective feature fusion. To handle large intra-class variance, small inter-class differences, and significant appearance variations of the same vehicle across different scenarios, ajoint loss function combining cross-entropy loss, contrastive loss, and center loss is introduced. The proposed method is trained and validated on the publicly available datasets RGBN300 and RGBNT100. The results show that compared with existing methods, the mean average precision (mAP) and the recognition accuracy of Rank-1, Rank-5, and Rank-10 are improved to varying degrees. Among them, mAP is improved by 20.6%, 29.0%, 5.0%, and 3.5% on the RGBN300 dataset, and 22.5%, 12.0%, 3.7%, and 3.0% on the RGBNT100 dataset. Rank-1, Rank-5, and Rank-10 of the RGBNT100 dataset achieves 95.1%, 96.7%, and 96.9%. The experimental results show that feature interaction and adaptive multi-modal fusion lead to more discriminative features and excellent vehicle re-identification performance.
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图 1 基于特征交互和多模态自适应融合的车辆再识别网络结构
Figure 1. Frame diagram of multi-modal vehicle re-identification network
表 1 参数设置
Table 1. Parameters setting
参数 值 图像尺寸 256×256 批大小 16 Epochs 120 Learning rate 40-td epoch 3.5×10-5 Learning rate 80-td epoch 3.5×10-6 
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表 2 不同参数γ在数据集RGBNT100的评价结果
Table 2. Different parameter γ and the corresponding evaluation results on the RGBNT100 dataset
γ EmAP/% ERank - 1/% 0.000 1 73.9 77.6 0.001 76.1 80.2 0.01 74.8 76.9 0.1 74.9 77.8 1 74.2 77.0
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表 3 不同车辆再识别算法的主干网络和超参数对比
Table 3. Comparisons of Backbone Networks and parameters of different vehicle Re-identification methods
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表 4 不同车辆再识别算法的实验结果对比
Table 4. Comparisons of experimental results of different vehicle Re-identification methods
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表 5 模态消融实验
Table 5. Ablation experiments of four groups
方法 RGBNT100 EmAP/% ERank - 1/% ERank - 5/% ERank - 10/% RGB 52.9 73.5 77.4 80.8 RGB+NIR 65.6 86.4 88.6 90.2 RGB+TIR 74.1 91.0 92.8 94.8 RGB+NIR+TIR 77.8 95.1 96.7 96.9
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表 6 损失函数消融实验
Table 6. Ablation experiments of different loss functions
方法 RGBNT100 EmAP/% ERank - 1/% ERank - 5/% ERank - 10/% Lcross 72.5 92.0 94.7 95.6 Lcontrast 73.6 88.9 91.1 92.0 Lcenter 3.8 4.2 7.2 8.9 Lcross + Lcontrast 74.9 94.9 95.8 96.1 Lcross + Lcenter 75.7 94.5 95.7 95.9 Lcontrast + Lcenter 76.3 91.8 93.4 94.3 Lcross + Lcontrast + Lcenter 77.8 95.1 96.7 96.9
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表 7 对比消融实验的8组实验配置
Table 7. Experiment configurations of the eight groups in the ablation experiment
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表 8 8组消融实验的结果
Table 8. Results of 8 ablation experiments
组 EmAP/% ERank - 1/% ERank - 5/% ERank - 10/% 1 67.7 87.9 89.2 91.4 2 68.5 89.6 90.4 93.3 3 71.8 90.5 92.1 93.9 4 73.2 91.8 93.5 94.7 5 71.2 90.3 91.8 93.1 6 72.9 91.7 92.6 94.2 7 74.6 93.2 94.5 95.1 8 77.8 95.1 96.7 96.9
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