/deep-high-resolution-net.pytorch

The project is an official implementation of our CVPR2019 paper "Deep High-Resolution Representation Learning for Human Pose Estimation"

Primary LanguageCudaMIT LicenseMIT

Deep High-Resolution Representation Learning for Human Pose Estimation (accepted to CVPR2019)

News

Introduction

This is an official pytorch implementation of Deep High-Resolution Representation Learning for Human Pose Estimation. In this work, we are interested in the human pose estimation problem with a focus on learning reliable high-resolution representations. Most existing methods recover high-resolution representations from low-resolution representations produced by a high-to-low resolution network. Instead, our proposed network maintains high-resolution representations through the whole process. We start from a high-resolution subnetwork as the first stage, gradually add high-to-low resolution subnetworks one by one to form more stages, and connect the mutli-resolution subnetworks in parallel. We conduct repeated multi-scale fusions such that each of the high-to-low resolution representations receives information from other parallel representations over and over, leading to rich high-resolution representations. As a result, the predicted keypoint heatmap is potentially more accurate and spatially more precise. We empirically demonstrate the effectiveness of our network through the superior pose estimation results over two benchmark datasets: the COCO keypoint detection dataset and the MPII Human Pose dataset.

Illustrating the architecture of the proposed HRNet

Main Results

Results on MPII val

Arch Head Shoulder Elbow Wrist Hip Knee Ankle Mean Mean@0.1
pose_resnet_50 96.4 95.3 89.0 83.2 88.4 84.0 79.6 88.5 34.0
pose_resnet_101 96.9 95.9 89.5 84.4 88.4 84.5 80.7 89.1 34.0
pose_resnet_152 97.0 95.9 90.0 85.0 89.2 85.3 81.3 89.6 35.0
pose_hrnet_w32 97.1 95.9 90.3 86.4 89.1 87.1 83.3 90.3 37.7

Note:

Results on COCO val2017 with detector having human AP of 56.4 on COCO val2017 dataset

Arch Input size #Params GFLOPs AP Ap .5 AP .75 AP (M) AP (L) AR AR .5 AR .75 AR (M) AR (L)
pose_resnet_50 256x192 34.0M 8.9 0.704 0.886 0.783 0.671 0.772 0.763 0.929 0.834 0.721 0.824
pose_resnet_50 384x288 34.0M 20.0 0.722 0.893 0.789 0.681 0.797 0.776 0.932 0.838 0.728 0.846
pose_resnet_101 256x192 53.0M 12.4 0.714 0.893 0.793 0.681 0.781 0.771 0.934 0.840 0.730 0.832
pose_resnet_101 384x288 53.0M 27.9 0.736 0.896 0.803 0.699 0.811 0.791 0.936 0.851 0.745 0.858
pose_resnet_152 256x192 68.6M 15.7 0.720 0.893 0.798 0.687 0.789 0.778 0.934 0.846 0.736 0.839
pose_resnet_152 384x288 68.6M 35.3 0.743 0.896 0.811 0.705 0.816 0.797 0.937 0.858 0.751 0.863
pose_hrnet_w32 256x192 28.5M 7.1 0.744 0.905 0.819 0.708 0.810 0.798 0.942 0.865 0.757 0.858
pose_hrnet_w32 384x288 28.5M 16.0 0.758 0.906 0.825 0.720 0.827 0.809 0.943 0.869 0.767 0.871
pose_hrnet_w48 256x192 63.6M 14.6 0.751 0.906 0.822 0.715 0.818 0.804 0.943 0.867 0.762 0.864
pose_hrnet_w48 384x288 63.6M 32.9 0.763 0.908 0.829 0.723 0.834 0.812 0.942 0.871 0.767 0.876

Note:

Results on COCO test-dev2017 with detector having human AP of 60.9 on COCO test-dev2017 dataset

Arch Input size #Params GFLOPs AP Ap .5 AP .75 AP (M) AP (L) AR AR .5 AR .75 AR (M) AR (L)
pose_resnet_152 384x288 68.6M 35.3 0.737 0.919 0.828 0.713 0.800 0.790 0.952 0.856 0.748 0.849
pose_hrnet_w48 384x288 63.6M 32.9 0.755 0.925 0.833 0.719 0.815 0.805 0.957 0.874 0.763 0.863
pose_hrnet_w48* 384x288 63.6M 32.9 0.770 0.927 0.845 0.734 0.831 0.820 0.960 0.886 0.778 0.877

Note:

Environment

The code is developed using python 3.6 on Ubuntu 16.04. NVIDIA GPUs are needed. The code is developed and tested using 4 NVIDIA P100 GPU cards. Other platforms or GPU cards are not fully tested.

Quick start

Installation

  1. Install pytorch >= v1.0.0 following official instruction. Note that if you use pytorch's version < v1.0.0, you should following the instruction at https://github.com/Microsoft/human-pose-estimation.pytorch to disable cudnn's implementations of BatchNorm layer. We encourage you to use higher pytorch's version(>=v1.0.0)

  2. Clone this repo, and we'll call the directory that you cloned as ${POSE_ROOT}.

  3. Install dependencies:

    pip install -r requirements.txt
    
  4. Make libs:

    cd ${POSE_ROOT}/lib
    make
    
  5. Install COCOAPI:

    # COCOAPI=/path/to/clone/cocoapi
    git clone https://github.com/cocodataset/cocoapi.git $COCOAPI
    cd $COCOAPI/PythonAPI
    # Install into global site-packages
    make install
    # Alternatively, if you do not have permissions or prefer
    # not to install the COCO API into global site-packages
    python3 setup.py install --user
    

    Note that instructions like # COCOAPI=/path/to/install/cocoapi indicate that you should pick a path where you'd like to have the software cloned and then set an environment variable (COCOAPI in this case) accordingly.

  6. Init output(training model output directory) and log(tensorboard log directory) directory:

    mkdir output 
    mkdir log
    

    Your directory tree should look like this:

    ${POSE_ROOT}
    ├── data
    ├── experiments
    ├── lib
    ├── log
    ├── models
    ├── output
    ├── tools 
    ├── README.md
    └── requirements.txt
    
  7. Download pretrained models from our model zoo(GoogleDrive or OneDrive)

    ${POSE_ROOT}
     `-- models
         `-- pytorch
             |-- imagenet
             |   |-- hrnet_w32-36af842e.pth
             |   |-- hrnet_w48-8ef0771d.pth
             |   |-- resnet50-19c8e357.pth
             |   |-- resnet101-5d3b4d8f.pth
             |   `-- resnet152-b121ed2d.pth
             |-- pose_coco
             |   |-- pose_hrnet_w32_256x192.pth
             |   |-- pose_hrnet_w32_384x288.pth
             |   |-- pose_hrnet_w48_256x192.pth
             |   |-- pose_hrnet_w48_384x288.pth
             |   |-- pose_resnet_101_256x192.pth
             |   |-- pose_resnet_101_384x288.pth
             |   |-- pose_resnet_152_256x192.pth
             |   |-- pose_resnet_152_384x288.pth
             |   |-- pose_resnet_50_256x192.pth
             |   `-- pose_resnet_50_384x288.pth
             `-- pose_mpii
                 |-- pose_hrnet_w32_256x256.pth
                 |-- pose_hrnet_w48_256x256.pth
                 |-- pose_resnet_101_256x256.pth
                 |-- pose_resnet_152_256x256.pth
                 `-- pose_resnet_50_256x256.pth
    
    

Data preparation

For MPII data, please download from MPII Human Pose Dataset. The original annotation files are in matlab format. We have converted them into json format, you also need to download them from OneDrive or GoogleDrive. Extract them under {POSE_ROOT}/data, and make them look like this:

${POSE_ROOT}
|-- data
`-- |-- mpii
    `-- |-- annot
        |   |-- gt_valid.mat
        |   |-- test.json
        |   |-- train.json
        |   |-- trainval.json
        |   `-- valid.json
        `-- images
            |-- 000001163.jpg
            |-- 000003072.jpg

For COCO data, please download from COCO download, 2017 Train/Val is needed for COCO keypoints training and validation. We also provide person detection result of COCO val2017 and test-dev2017 to reproduce our multi-person pose estimation results. Please download from OneDrive or GoogleDrive. Download and extract them under {POSE_ROOT}/data, and make them look like this:

${POSE_ROOT}
|-- data
`-- |-- coco
    `-- |-- annotations
        |   |-- person_keypoints_train2017.json
        |   `-- person_keypoints_val2017.json
        |-- person_detection_results
        |   |-- COCO_val2017_detections_AP_H_56_person.json
        |   |-- COCO_test-dev2017_detections_AP_H_609_person.json
        `-- images
            |-- train2017
            |   |-- 000000000009.jpg
            |   |-- 000000000025.jpg
            |   |-- 000000000030.jpg
            |   |-- ... 
            `-- val2017
                |-- 000000000139.jpg
                |-- 000000000285.jpg
                |-- 000000000632.jpg
                |-- ... 

Training and Testing

Testing on MPII dataset using model zoo's models(GoogleDrive or OneDrive)

python tools/test.py \
    --cfg experiments/mpii/hrnet/w32_256x256_adam_lr1e-3.yaml \
    TEST.MODEL_FILE models/pytorch/pose_mpii/pose_hrnet_w32_256x256.pth

Training on MPII dataset

python tools/train.py \
    --cfg experiments/mpii/hrnet/w32_256x256_adam_lr1e-3.yaml

Testing on COCO val2017 dataset using model zoo's models(GoogleDrive or OneDrive)

python tools/test.py \
    --cfg experiments/coco/hrnet/w32_256x192_adam_lr1e-3.yaml \
    TEST.MODEL_FILE models/pytorch/pose_coco/pose_hrnet_w32_256x192.pth \
    TEST.USE_GT_BBOX False

Training on COCO train2017 dataset

python tools/train.py \
    --cfg experiments/coco/hrnet/w32_256x192_adam_lr1e-3.yaml \

Other applications

Many other dense prediction tasks, such as segmentation, face alignment and object detection, etc. have been benefited by HRNet. More information can be found at Deep High-Resolution Representation Learning.

Citation

If you use our code or models in your research, please cite with:

@inproceedings{sun2019deep,
  title={Deep High-Resolution Representation Learning for Human Pose Estimation},
  author={Sun, Ke and Xiao, Bin and Liu, Dong and Wang, Jingdong},
  booktitle={CVPR},
  year={2019}
}

@inproceedings{xiao2018simple,
    author={Xiao, Bin and Wu, Haiping and Wei, Yichen},
    title={Simple Baselines for Human Pose Estimation and Tracking},
    booktitle = {European Conference on Computer Vision (ECCV)},
    year = {2018}
}