README_en.md

简体中文 | English

KeyPoint Detection Models

Content

• Introduction
• Model Recommendation
• Model Zoo
• Getting Start
  • Environmental Installation
  • Dataset Preparation
  • Training and Testing
    • Training on single GPU
    • Training on multiple GPU
    • Evaluation
    • Inference
    • Deploy Inference
      • Deployment for Top-Down models
      • Deployment for Bottom-Up models
      • joint inference with Multi-Object Tracking model FairMOT

Introduction

The keypoint detection part in PaddleDetection follows the state-of-the-art algorithm closely, including Top-Down and Bottom-Up methods, which can satisfy the different needs of users.

Top-Down detects the object first and then detect the specific keypoint. The accuracy of Top-Down models will be higher, but the time required will increase by the number of objects.

Differently, Bottom-Up detects the point first and then group or connect those points to form several instances of human pose. The speed of Bottom-Up is fixed and will not increase by the number of objects, but the accuracy will be lower.

At the same time, PaddleDetection provides PP-TinyPose specially for mobile devices.

Model Recommendation

Mobile Terminal

Detection Model	Keypoint Model	Input Size	Accuracy of COCO	Average Inference Time (FP16)	Model Weight	Paddle-Lite Inference Model（FP16)
PicoDet-S-Pedestrian	PP-TinyPose	Detection：192x192 Keypoint：128x96	Detection mAP：29.0 Keypoint AP：58.1	Detection：2.37ms Keypoint：3.27ms	Detection Keypoint	Detection Keypoint
PicoDet-S-Pedestrian	PP-TinyPose	Detection：320x320 Keypoint：256x192	Detection mAP：38.5 Keypoint AP：68.8	Detection：6.30ms Keypoint：8.33ms	Detection Keypoint	Detection Keypoint

*Specific documents of PP-TinyPose, please refer to Document。

Teminal Server

Detection Model	Keypoint Model	Input Size	Accuracy of COCO	Model Weight
PP-YOLOv2	HRNet-w32	Detection：640x640 Keypoint：384x288	Detection mAP：49.5 Keypoint AP：77.8	Detection Keypoint
PP-YOLOv2	HRNet-w32	Detection：640x640 Keypoint：256x192	Detection mAP：49.5 Keypoint AP：76.9	Detection Keypoint

Model Zoo

COCO Dataset

Model	Input Size	AP(coco val)	Model Download	Config File
HigherHRNet-w32	512	67.1	higherhrnet_hrnet_w32_512.pdparams	config
HigherHRNet-w32	640	68.3	higherhrnet_hrnet_w32_640.pdparams	config
HigherHRNet-w32+SWAHR	512	68.9	higherhrnet_hrnet_w32_512_swahr.pdparams	config
HRNet-w32	256x192	76.9	hrnet_w32_256x192.pdparams	config
HRNet-w32	384x288	77.8	hrnet_w32_384x288.pdparams	config
HRNet-w32+DarkPose	256x192	78.0	dark_hrnet_w32_256x192.pdparams	config
HRNet-w32+DarkPose	384x288	78.3	dark_hrnet_w32_384x288.pdparams	config
WiderNaiveHRNet-18	256x192	67.6(+DARK 68.4)	wider_naive_hrnet_18_256x192_coco.pdparams	config
LiteHRNet-18	256x192	66.5	lite_hrnet_18_256x192_coco.pdparams	config
LiteHRNet-18	384x288	69.7	lite_hrnet_18_384x288_coco.pdparams	config
LiteHRNet-30	256x192	69.4	lite_hrnet_30_256x192_coco.pdparams	config
LiteHRNet-30	384x288	72.5	lite_hrnet_30_384x288_coco.pdparams	config

Note：The AP results of Top-Down models are based on bounding boxes in GroundTruth.

MPII Dataset

Model	Input Size	PCKh(Mean)	PCKh(Mean@0.1)	Model Download	Config File
HRNet-w32	256x256	90.6	38.5	hrnet_w32_256x256_mpii.pdparams	config

We also release PP-TinyPose, a real-time keypoint detection model optimized for mobile devices. Welcome to experience.

Getting Start

1.Environmental Installation

​ Please refer to PaddleDetection Installation Guild to install PaddlePaddle and PaddleDetection correctly.

2.Dataset Preparation

​ Currently, KeyPoint Detection Models support COCO and MPII. Please refer to Keypoint Dataset Preparation to prepare dataset.

​ About the description for config files, please refer to Keypoint Config Guild.

• Note that, when testing by detected bounding boxes in Top-Down method, We should get bbox.json by a detection model. You can download the detected results for COCO val2017 (Detector having human AP of 56.4 on COCO val2017 dataset) directly, put it at the root path (PaddleDetection/), and set use_gt_bbox: False in config file.

3.Training and Testing

Training on single GPU

#COCO DataSet
CUDA_VISIBLE_DEVICES=0 python3 tools/train.py -c configs/keypoint/higherhrnet/higherhrnet_hrnet_w32_512.yml

#MPII DataSet
CUDA_VISIBLE_DEVICES=0 python3 tools/train.py -c configs/keypoint/hrnet/hrnet_w32_256x256_mpii.yml

Training on multiple GPU

#COCO DataSet
CUDA_VISIBLE_DEVICES=0,1,2,3 python3 -m paddle.distributed.launch tools/train.py -c configs/keypoint/higherhrnet/higherhrnet_hrnet_w32_512.yml

#MPII DataSet
CUDA_VISIBLE_DEVICES=0,1,2,3 python3 -m paddle.distributed.launch tools/train.py -c configs/keypoint/hrnet/hrnet_w32_256x256_mpii.yml

Evaluation

#COCO DataSet
CUDA_VISIBLE_DEVICES=0 python3 tools/eval.py -c configs/keypoint/higherhrnet/higherhrnet_hrnet_w32_512.yml

#MPII DataSet
CUDA_VISIBLE_DEVICES=0 python3 tools/eval.py -c configs/keypoint/hrnet/hrnet_w32_256x256_mpii.yml

#If you only need the prediction result, you can set --save_prediction_only. Then the result will be saved at output/keypoints_results.json by default.
CUDA_VISIBLE_DEVICES=0 python3 tools/eval.py -c configs/keypoint/higherhrnet/higherhrnet_hrnet_w32_512.yml --save_prediction_only

Inference

​ Note：Top-down models only support inference for a cropped image with single person. If you want to do inference on image with several people, please see "joint inference by detection and keypoint". Or you can choose a Bottom-up model.

CUDA_VISIBLE_DEVICES=0 python3 tools/infer.py -c configs/keypoint/higherhrnet/higherhrnet_hrnet_w32_512.yml -o weights=./output/higherhrnet_hrnet_w32_512/model_final.pdparams --infer_dir=../images/ --draw_threshold=0.5 --save_txt=True

Deploy Inference

Deployment for Top-Down models

#Export Detection Model
python tools/export_model.py -c configs/ppyolo/ppyolov2_r50vd_dcn_365e_coco.yml -o weights=https://paddledet.bj.bcebos.com/models/ppyolov2_r50vd_dcn_365e_coco.pdparams 

#Export Keypoint Model
python tools/export_model.py -c configs/keypoint/hrnet/hrnet_w32_256x192.yml -o weights=https://paddledet.bj.bcebos.com/models/keypoint/hrnet_w32_256x192.pdparams

#Deployment for detector and keypoint, which is only for Top-Down models
python deploy/python/det_keypoint_unite_infer.py --det_model_dir=output_inference/ppyolo_r50vd_dcn_2x_coco/ --keypoint_model_dir=output_inference/hrnet_w32_384x288/ --video_file=../video/xxx.mp4  --device=gpu

Deployment for Bottom-Up models

#Export model
python tools/export_model.py -c configs/keypoint/higherhrnet/higherhrnet_hrnet_w32_512.yml -o weights=output/higherhrnet_hrnet_w32_512/model_final.pdparams


#Keypoint independent deployment, which is only for bottom-up models
python deploy/python/keypoint_infer.py --model_dir=output_inference/higherhrnet_hrnet_w32_512/ --image_file=./demo/000000014439_640x640.jpg --device=gpu --threshold=0.5

joint inference with Multi-Object Tracking model FairMOT

#export FairMOT model
python tools/export_model.py -c configs/mot/fairmot/fairmot_dla34_30e_1088x608.yml -o weights=https://paddledet.bj.bcebos.com/models/mot/fairmot_dla34_30e_1088x608.pdparams

#joint inference with Multi-Object Tracking model FairMOT
python deploy/python/mot_keypoint_unite_infer.py --mot_model_dir=output_inference/fairmot_dla34_30e_1088x608/ --keypoint_model_dir=output_inference/higherhrnet_hrnet_w32_512/ --video_file={your video name}.mp4 --device=GPU

Note: To export MOT model, please refer to Here.

Reference

@inproceedings{cheng2020bottom,
  title={HigherHRNet: Scale-Aware Representation Learning for Bottom-Up Human Pose Estimation},
  author={Bowen Cheng and Bin Xiao and Jingdong Wang and Honghui Shi and Thomas S. Huang and Lei Zhang},
  booktitle={CVPR},
  year={2020}
}

@inproceedings{SunXLW19,
  title={Deep High-Resolution Representation Learning for Human Pose Estimation},
  author={Ke Sun and Bin Xiao and Dong Liu and Jingdong Wang},
  booktitle={CVPR},
  year={2019}
}

@article{wang2019deep,
  title={Deep High-Resolution Representation Learning for Visual Recognition},
  author={Wang, Jingdong and Sun, Ke and Cheng, Tianheng and Jiang, Borui and Deng, Chaorui and Zhao, Yang and Liu, Dong and Mu, Yadong and Tan, Mingkui and Wang, Xinggang and Liu, Wenyu and Xiao, Bin},
  journal={TPAMI},
  year={2019}
}

@InProceedings{Zhang_2020_CVPR,
    author = {Zhang, Feng and Zhu, Xiatian and Dai, Hanbin and Ye, Mao and Zhu, Ce},
    title = {Distribution-Aware Coordinate Representation for Human Pose Estimation},
    booktitle = {IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR)},
    month = {June},
    year = {2020}
}

@inproceedings{Yulitehrnet21,
  title={Lite-HRNet: A Lightweight High-Resolution Network},
  author={Yu, Changqian and Xiao, Bin and Gao, Changxin and Yuan, Lu and Zhang, Lei and Sang, Nong and Wang, Jingdong},
  booktitle={CVPR},
  year={2021}
}