2021-06-17 20:40:50 +08:00
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# 车辆识别
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此部分主要包含两部分:车辆细粒度分类、车辆ReID。
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细粒度分类,是对属于某一类基础类别的图像进行子类别的细粉,如各种鸟、各种花、各种矿石之间。顾名思义,车辆细粒度分类是对车辆的不同子类别进行分类。
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ReID,也就是 Re-identification,其定义是利用算法,在图像库中找到要搜索的目标的技术,所以它是属于图像检索的一个子问题。而车辆ReID就是给定一张车辆图像,找出同一摄像头不同的拍摄图像,或者不同摄像头下拍摄的同一车辆图像的过程。在此过程中,如何提取鲁棒特征,尤为重要。
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此文档中,使用同一套训练方案对两个细方向分别做了尝试。
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## 1 算法介绍
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算法整体流程,详见[特征学习](./feature_learning.md)整体流程。
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车辆ReID整体设置详见: [ResNet50_ReID.yaml](../../../ppcls/configs/Vehicle/ResNet50_ReID.yaml)。
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车辆细分类整体设置详见:[ResNet50.yaml](../../../ppcls/configs/Vehicle/ResNet50.yaml)
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具体细节如下所示。
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### 1.1数据增强
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与普通训练分类不同,此部分主要使用如下图像增强方式:
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- 图像`Resize`到224。尤其对于ReID而言,车辆图像已经是由检测器检测后crop出的车辆图像,因此若再使用crop图像增强,会丢失更多的车辆信息
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- [AugMix](https://arxiv.org/abs/1912.02781v1):模拟光照变化、摄像头位置变化等实际场景
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- [RandomErasing](https://arxiv.org/pdf/1708.04896v2.pdf):模拟遮挡等实际情况
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### 1.2 Backbone的具体设置
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使用`ResNet50`作为backbone,同时做了如下修改:
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- last stage stride=1, 保持最后输出特征图尺寸14x14。计算量增加较小,但显著提高模型特征提取能力
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具体代码:[ResNet50_last_stage_stride1](../../../ppcls/arch/backbone/variant_models/resnet_variant.py)
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### 1.3 Neck部分
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为了降低inferecne时计算特征距离的复杂度,添加一个embedding 卷积层,特征维度为512。
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### 1.4 Metric Learning相关Loss的设置
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2021-06-29 15:08:29 +08:00
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车辆ReID及细粒度分类中,使用了[SupConLoss](../../../ppcls/loss/supconloss.py) + [ArcLoss](../../../ppcls/arch/gears/arcmargin.py),其中权重比例为1:1
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2021-06-17 20:40:50 +08:00
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## 2 实验结果
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### 2.1 车辆ReID
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<img src="../../images/recognition/vehicle/cars.JPG" style="zoom:50%;" />
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此方法在VERI-Wild数据集上进行了实验。此数据集是在一个大型闭路电视监控系统,在无约束的场景下,一个月内(30*24小时)中捕获的。该系统由174个摄像头组成,其摄像机分布在200多平方公里的大型区域。原始车辆图像集包含1200万个车辆图像,经过数据清理和标注,采集了416314张40671个不同的车辆图像。[具体详见论文](https://github.com/PKU-IMRE/VERI-Wild)
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| **Methods** | **Small** | | |
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| :--------------------------: | :-------: | :-------: | :-------: |
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| | mAP | Top1 | Top5 |
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| Strong baesline(Resnet50)[1] | 76.61 | 90.83 | 97.29 |
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| HPGN(Resnet50+PGN)[2] | 80.42 | 91.37 | - |
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| GLAMOR(Resnet50+PGN)[3] | 77.15 | 92.13 | 97.43 |
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| PVEN(Resnet50)[4] | 79.8 | 94.01 | 98.06 |
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| SAVER(VAE+Resnet50)[5] | 80.9 | 93.78 | 97.93 |
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| PaddleClas baseline1 | 65.6 | 92.37 | 97.23 |
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| PaddleClas baseline2 | 80.09 | **93.81** | **98.26** |
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注:baseline1 为目前的开源模型,baseline2即将开源
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### 2.2 车辆细分类
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车辆细分类中,使用[CompCars](http://mmlab.ie.cuhk.edu.hk/datasets/comp_cars/index.html)作为训练数据集。
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数据集中图像主要来自网络和监控数据,其中网络数据包含163个汽车制造商、1716个汽车型号的汽车。共**136,726**张全车图像,**27,618**张部分车图像。其中网络汽车数据包含bounding box、视角、5个属性(最大速度、排量、车门数、车座数、汽车类型)。监控数据包含**50,000**张前视角图像。
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值得注意的是,此数据集中需要根据自己的需要生成不同的label,如本demo中,将不同年份生产的相同型号的车辆视为同一类,因此,类别总数为:431类。
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2021-06-29 15:08:29 +08:00
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| **Methods** | Top1 Acc |
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| :-----------------------------: | :--------: |
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| ResNet101-swp[6] | 97.6% |
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| Fine-Tuning DARTS[7] | 95.9% |
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| Resnet50 + COOC[8] | 95.6% |
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| A3M[9] | 95.4% |
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| PaddleClas baseline (ResNet50) | **97.37**% |
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2021-06-17 20:40:50 +08:00
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## 3 参考文献
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[1] Bag of Tricks and a Strong Baseline for Deep Person Re-Identification.CVPR workshop 2019.
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[2] Exploring Spatial Significance via Hybrid Pyramidal Graph Network for Vehicle Re-identification. In arXiv preprint arXiv:2005.14684
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[3] GLAMORous: Vehicle Re-Id in Heterogeneous Cameras Networks with Global and Local Attention. In arXiv preprint arXiv:2002.02256
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[4] Parsing-based view-aware embedding network for vehicle re-identification. CVPR 2020.
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[5] The Devil is in the Details: Self-Supervised Attention for Vehicle Re-Identification. In ECCV 2020.
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[6] Deep CNNs With Spatially Weighted Pooling for Fine-Grained Car Recognition. IEEE Transactions on Intelligent Transportation Systems, 2017.
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[7] Fine-Tuning DARTS for Image Classification. 2020.
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[8] Fine-Grained Vehicle Classification with Unsupervised Parts Co-occurrence Learning. 2018
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[9] Attribute-Aware Attention Model for Fine-grained Representation Learning. 2019.
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