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YOLOv5 Series Multi-backbone(TPH-YOLOv5, Ghostnet, ShuffleNetv2, Mobilenetv3Small, EfficientNetLite, PP-LCNet, SwinTransformer YOLO), Module(CBAM, DCN), Pruning (EagleEye, Network Slimming), Quantization (MQBench) and Deployment (TensorRT, ncnn) Compression Tool Box.

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Gumpest/YOLOv5-Multibackbone-Compression

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YOLOv5-Compression

2021.10.30 复现TPH-YOLOv5

2021.10.31 完成替换backbone为Ghostnet

2021.11.02 完成替换backbone为Shufflenetv2

2021.11.05 完成替换backbone为Mobilenetv3Small

2021.11.10 完成EagleEye对YOLOv5系列剪枝支持

2021.11.14 完成MQBench对YOLOv5系列量化支持

2021.11.16 完成替换backbone为EfficientNetLite-0

2021.11.26 完成替换backbone为PP-LCNet-1x

2021.12.12 完成SwinTrans-YOLOv5(C3STR)

2021.12.15 完成Slimming对YOLOv5系列剪枝支持

Requirements

pip install -r requirements.txt

Multi-Backbone Substitution for YOLOs

1、Base Model

Train on Visdrone DataSet (Input size is 608)

No. Model mAP mAP@50 Parameters(M) GFLOPs
1 YOLOv5n 13.0 26.20 1.78 4.2
2 YOLOv5s 18.4 34.00 7.05 15.9
3 YOLOv5m 21.6 37.80 20.91 48.2
4 YOLOv5l 23.2 39.70 46.19 108.1
5 YOLOv5x 24.3 40.80 86.28 204.4

2、Higher Precision Model

A、TPH-YOLOv5

Train on Visdrone DataSet (6-7 size is 640,8 size is 1536)

No. Model mAP mAP@50 Parameters(M) GFLOPs
6 YOLOv5xP2 30.0 49.29 90.96 314.2
7 YOLOv5xP2 CBAM 30.1 49.40 91.31 315.1
8 YOLOv5x-TPH 40.7 63.00 112.97 270.8
Usage:
nohup python train.py --data VisDrone.yaml --weights yolov5n.pt --cfg models/yolov5n.yaml --epochs 300 --batch-size 8 --img 608 --device 0,1 --sync-bn >> yolov5n.txt &
Composition:

P2 Head、CBAM、TPH、BiFPN、SPP

TPH-YOLOv5

1、TransBlock的数量会根据YOLO规模的不同而改变,标准结构作用于YOLOv5m

2、当YOLOv5x为主体与标准结构的区别是:(1)首先去掉14和19的CBAM模块(2)降低与P2关联的通道数(128)(3)在输出头之前会添加SPP模块,注意SPP的kernel随着P的像素减小而减小(4)在CBAM之后进行输出(5)只保留backbone以及最后一层输出的TransBlock(6)采用BiFPN作为neck

3、更改不同Loss分支的权重:如下图,当训练集的分类与置信度损失还在下降时,验证集的分类与置信度损失开始反弹,说明出现了过拟合,需要降低这两个任务的权重

消融实验如下:

box cls obj acc
0.05 0.5 1.0 37.90
0.05 0.3 0.7 38.00
0.05 0.2 0.4 37.5

loss

B、SwinTrans-YOLOv5

pip install timm
Usage:
python train.py --data VisDrone.yaml --weights yolov5x.pt --cfg models/accModels/yolov5xP2CBAM-Swin-BiFPN-SPP.yaml --hyp data/hyps/hyp.visdrone.yaml --epochs 60 --batch-size 4 --img 1536 --nohalf

(1)Window size由7替换为检测任务常用分辨率的公约数8

(2)create_mask封装为函数,由在init函数执行变为在forward函数执行

(3)若分辨率小于window size或不是其公倍数时,在其右侧和底部Padding

debug:在计算完之后需要反padding回去,否则与cv2支路的img_size无法对齐

(4)forward函数前后对输入输出reshape

(5)验证C3STR时,需要手动关闭默认模型在half精度下验证(--nohalf

3、Slighter Model

Train on Visdrone DataSet (1 size is 608,2-6 size is 640)

No Model mAP mAP@50 Parameters(M) GFLOPs TrainCost(h) Memory Cost(G) PT File FPS@CPU
1 YOLOv5l 23.2 39.7 46.19 108.1
2 YOLOv5l-GhostNet 18.4 33.8 24.27 42.4 27.44 4.97 PekingUni Cloud
3 YOLOv5l-ShuffleNetV2 16.48 31.1 21.27 40.5 10.98 2.41 PekingUni Cloud
4 YOLOv5l-MobileNetv3Small 16.55 31.2 20.38 38.4 10.19 5.30 PekingUni Cloud
5 YOLOv5l-EfficientNetLite0 19.12 35 23.01 43.9 13.94 2.04 PekingUni Cloud
6 YOLOv5l-PP-LCNet 17.63 32.8 21.64 41.7 18.52 1.66 PekingUni Cloud

A、GhostNet-YOLOv5

GhostNet

(1)为保持一致性,下采样的DW的kernel_size均等于3

(2)neck部分与head部分沿用YOLOv5l原结构

(3)中间通道人为设定(expand)

B、ShuffleNetV2-YOLOv5

Shffulenet

(1)Focus Layer不利于芯片部署,频繁的slice操作会让缓存占用严重

(2)避免多次使用C3 Leyer以及高通道的C3 Layer(违背G1与G3准则)

(3)中间通道不变

C、MobileNetv3Small-YOLOv5

Mobilenetv3s

(1)原文结构,部分使用Hard-Swish激活函数以及SE模块

(2)Neck与head部分嫁接YOLOv5l原结构

(3)中间通道人为设定(expand)

D、EfficientNetLite0-YOLOv5

efficientlite

(1)使用Lite0结构,且不使用SE模块

(2)针对dropout_connect_rate,手动赋值(随着idx_stage变大而变大)

(3)中间通道一律*6(expand)

E、PP-LCNet-YOLOv5

PP-LCNet

(1)使用PP-LCNet-1x结构,在网络末端使用SE以及5*5卷积核

(2)SeBlock压缩维度为原1/16

(3)中间通道不变

Pruning for YOLOs

Model mAP mAP@50 Parameters(M) GFLOPs FPS@CPU
YOLOv5s 18.4 34 7.05 15.9
YOLOv5n 13 26.2 1.78 4.2
YOLOv5s-EagleEye@0.6 14.3 27.9 4.59 9.6

1、Prune Strategy

(1)基于YOLOv5块状结构设计,对Conv、C3、SPP(F)模块进行剪枝,具体来说有以下:

  • Conv模块的输出通道数
  • C3模块中cv2块和cv3块的输出通道数
  • C3模块中若干个bottleneck中的cv1块的输出通道数

(2)八倍通道剪枝(outchannel = 8*n)

(3)ShortCut、concat皆合并剪枝

2、Prune Tools

(1)EagleEye

EagleEye: Fast Sub-net Evaluation for Efficient Neural Network Pruning

基于搜索的通道剪枝方法,核心思想是随机搜索到大量符合目标约束的子网,然后快速更新校准BN层的均值与方差参数,并在验证集上测试校准后全部子网的精度。精度最高的子网拥有最好的架构,经微调恢复后能达到较高的精度。

eagleeye

Usage
  1. 正常训练模型
python train.py --data data/VisDrone.yaml --imgsz 640 --weights yolov5s.pt --cfg models/prunModels/yolov5s-pruning.yaml --device 0

(注意训练其他模型,参考/prunModels/yolov5s-pruning.yaml进行修改,目前已支持v6架构)

  1. 搜索最优子网
python pruneEagleEye.py --weights path_to_trained_yolov5_model --cfg models/prunModels/yolov5s-pruning.yaml --data data/VisDrone.yaml --path path_to_pruned_yolov5_yaml --max_iter maximum number of arch search --remain_ratio the whole FLOPs remain ratio --delta 0.02
  1. 微调恢复精度
python train.py --data data/VisDrone.yaml --imgsz 640 --weights path_to_Eaglepruned_yolov5_model --cfg path_to_pruned_yolov5_yaml --device 0

(2)Network Slimming

Learning Efficient Convolutional Networks through Network Slimming

Usage
  1. 模型BatchNorm Layer \gamma 稀疏化训练
python train.py --data data/VisDrone.yaml --imgsz 640 --weights yolov5s.pt --cfg models/prunModels/yolov5s-pruning.yaml --device 0 --sparse

(注意训练其他模型,参考/prunModels/yolov5s-pruning.yaml进行修改,目前已支持v6架构)

  1. BatchNorm Layer剪枝
python pruneSlim.py --weights path_to_sparsed_yolov5_model --cfg models/prunModels/yolov5s-pruning.yaml --data data/VisDrone.yaml --path path_to_pruned_yolov5_yaml --global_percent 0.6 --device 3
  1. 微调恢复精度
python train.py --data data/VisDrone.yaml --imgsz 640 --weights path_to_Slimpruned_yolov5_model --cfg path_to_pruned_yolov5_yaml --device 0

Quantize Aware Training for YOLOs

MQBench是实际硬件部署下评估量化算法的框架,进行各种适合于硬件部署的量化训练(QAT)

Requirements

  • PyTorch == 1.8.1

Install MQBench Lib

由于MQBench目前还在不断更新,选择0.0.2稳定版本作为本仓库的量化库。

git clone https://github.com/ZLkanyo009/MQBench.git
cd MQBench
python setup.py build
python setup.py install

Usage

训练脚本实例:

python train.py --data VisDrone.yaml --weights yolov5n.pt --cfg models/yolov5n.yaml --epochs 300 --batch-size 8 --img 608 --nosave --device 0,1 --sync-bn --quantize --BackendType NNIE

Deploy

目前已支持TensorRT及NCNN部署,详见YOLOv5-Multibackbone-Compression/deploy

To do

  • Multibackbone: MobileNetV3-small
  • Multibackbone: ShuffleNetV2
  • Multibackbone: GhostNet
  • Multibackbone: EfficientNet-Lite0
  • Multibackbone: PP-LCNet
  • Multibackbone: TPH-YOLOv5
  • Module: SwinTrans(C3STR)
  • Module: Deformable Convolution
  • Pruner: Network Slimming
  • Pruner: EagleEye
  • Pruner: OneShot (L1, L2, FPGM), ADMM, NetAdapt, Gradual, End2End
  • Quantization: MQBench
  • Knowledge Distillation

Acknowledge

感谢TPH-YOLOv5作者Xingkui Zhu

官方实现cv516Buaa/tph-yolov5 (github.com)

感谢ZJU-lishuang/yolov5_prune: yolov5剪枝,支持v2,v3,v4,v6版本的yolov5 (github.com)

About

YOLOv5 Series Multi-backbone(TPH-YOLOv5, Ghostnet, ShuffleNetv2, Mobilenetv3Small, EfficientNetLite, PP-LCNet, SwinTransformer YOLO), Module(CBAM, DCN), Pruning (EagleEye, Network Slimming), Quantization (MQBench) and Deployment (TensorRT, ncnn) Compression Tool Box.

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