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microsoft / Human Pose Estimation.pytorch

Licence: mit
The project is an official implement of our ECCV2018 paper "Simple Baselines for Human Pose Estimation and Tracking(https://arxiv.org/abs/1804.06208)"

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Simple Baselines for Human Pose Estimation and Tracking

News

Introduction

This is an official pytorch implementation of Simple Baselines for Human Pose Estimation and Tracking. This work provides baseline methods that are surprisingly simple and effective, thus helpful for inspiring and evaluating new ideas for the field. State-of-the-art results are achieved on challenging benchmarks. On COCO keypoints valid dataset, our best single model achieves 74.3 of mAP. You can reproduce our results using this repo. All models are provided for research purpose.

Main Results

Results on MPII val

Arch Head Shoulder Elbow Wrist Hip Knee Ankle Mean [email protected]
256x256_pose_resnet_50_d256d256d256 96.351 95.329 88.989 83.176 88.420 83.960 79.594 88.532 33.911
384x384_pose_resnet_50_d256d256d256 96.658 95.754 89.790 84.614 88.523 84.666 79.287 89.066 38.046
256x256_pose_resnet_101_d256d256d256 96.862 95.873 89.518 84.376 88.437 84.486 80.703 89.131 34.020
384x384_pose_resnet_101_d256d256d256 96.965 95.907 90.268 85.780 89.597 85.935 82.098 90.003 38.860
256x256_pose_resnet_152_d256d256d256 97.033 95.941 90.046 84.976 89.164 85.311 81.271 89.620 35.025
384x384_pose_resnet_152_d256d256d256 96.794 95.618 90.080 86.225 89.700 86.862 82.853 90.200 39.433

Note:

  • Flip test is used.

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

Arch AP Ap .5 AP .75 AP (M) AP (L) AR AR .5 AR .75 AR (M) AR (L)
256x192_pose_resnet_50_d256d256d256 0.704 0.886 0.783 0.671 0.772 0.763 0.929 0.834 0.721 0.824
384x288_pose_resnet_50_d256d256d256 0.722 0.893 0.789 0.681 0.797 0.776 0.932 0.838 0.728 0.846
256x192_pose_resnet_101_d256d256d256 0.714 0.893 0.793 0.681 0.781 0.771 0.934 0.840 0.730 0.832
384x288_pose_resnet_101_d256d256d256 0.736 0.896 0.803 0.699 0.811 0.791 0.936 0.851 0.745 0.858
256x192_pose_resnet_152_d256d256d256 0.720 0.893 0.798 0.687 0.789 0.778 0.934 0.846 0.736 0.839
384x288_pose_resnet_152_d256d256d256 0.743 0.896 0.811 0.705 0.816 0.797 0.937 0.858 0.751 0.863

Results on Caffe-style ResNet

Arch AP Ap .5 AP .75 AP (M) AP (L) AR AR .5 AR .75 AR (M) AR (L)
256x192_pose_resnet_50_caffe_d256d256d256 0.704 0.914 0.782 0.677 0.744 0.735 0.921 0.805 0.704 0.783
256x192_pose_resnet_101_caffe_d256d256d256 0.720 0.915 0.803 0.693 0.764 0.753 0.928 0.821 0.720 0.802
256x192_pose_resnet_152_caffe_d256d256d256 0.728 0.925 0.804 0.702 0.766 0.760 0.931 0.828 0.729 0.806

Note:

  • Flip test is used.
  • Person detector has person AP of 56.4 on COCO val2017 dataset.
  • Difference between PyTorch-style and Caffe-style ResNet is the position of stride=2 convolution

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 >= v0.4.0 following official instruction.

  2. Disable cudnn for batch_norm:

    # PYTORCH=/path/to/pytorch
    # for pytorch v0.4.0
    sed -i "1194s/torch\.backends\.cudnn\.enabled/False/g" ${PYTORCH}/torch/nn/functional.py
    # for pytorch v0.4.1
    sed -i "1254s/torch\.backends\.cudnn\.enabled/False/g" ${PYTORCH}/torch/nn/functional.py
    

    Note that instructions like # PYTORCH=/path/to/pytorch indicate that you should pick a path where you'd like to have pytorch installed and then set an environment variable (PYTORCH in this case) accordingly.

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

  4. Install dependencies:

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

    cd ${POSE_ROOT}/lib
    make
    
  6. 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.

  7. Download pytorch imagenet pretrained models from pytorch model zoo and caffe-style pretrained models from GoogleDrive.

  8. Download mpii and coco pretrained models from OneDrive or GoogleDrive. Please download them under ${POSE_ROOT}/models/pytorch, and make them look like this:

    ${POSE_ROOT}
     `-- models
         `-- pytorch
             |-- imagenet
             |   |-- resnet50-19c8e357.pth
             |   |-- resnet50-caffe.pth.tar
             |   |-- resnet101-5d3b4d8f.pth
             |   |-- resnet101-caffe.pth.tar
             |   |-- resnet152-b121ed2d.pth
             |   `-- resnet152-caffe.pth.tar
             |-- pose_coco
             |   |-- pose_resnet_101_256x192.pth.tar
             |   |-- pose_resnet_101_384x288.pth.tar
             |   |-- pose_resnet_152_256x192.pth.tar
             |   |-- pose_resnet_152_384x288.pth.tar
             |   |-- pose_resnet_50_256x192.pth.tar
             |   `-- pose_resnet_50_384x288.pth.tar
             `-- pose_mpii
                 |-- pose_resnet_101_256x256.pth.tar
                 |-- pose_resnet_101_384x384.pth.tar
                 |-- pose_resnet_152_256x256.pth.tar
                 |-- pose_resnet_152_384x384.pth.tar
                 |-- pose_resnet_50_256x256.pth.tar
                 `-- pose_resnet_50_384x384.pth.tar
    
    
  9. 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
    ├── pose_estimation
    ├── README.md
    └── requirements.txt
    

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 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
        `-- images
            |-- train2017
            |   |-- 000000000009.jpg
            |   |-- 000000000025.jpg
            |   |-- 000000000030.jpg
            |   |-- ... 
            `-- val2017
                |-- 000000000139.jpg
                |-- 000000000285.jpg
                |-- 000000000632.jpg
                |-- ... 

Valid on MPII using pretrained models

python pose_estimation/valid.py \
    --cfg experiments/mpii/resnet50/256x256_d256x3_adam_lr1e-3.yaml \
    --flip-test \
    --model-file models/pytorch/pose_mpii/pose_resnet_50_256x256.pth.tar

Training on MPII

python pose_estimation/train.py \
    --cfg experiments/mpii/resnet50/256x256_d256x3_adam_lr1e-3.yaml

Valid on COCO val2017 using pretrained models

python pose_estimation/valid.py \
    --cfg experiments/coco/resnet50/256x192_d256x3_adam_lr1e-3.yaml \
    --flip-test \
    --model-file models/pytorch/pose_coco/pose_resnet_50_256x192.pth.tar

Training on COCO train2017

python pose_estimation/train.py \
    --cfg experiments/coco/resnet50/256x192_d256x3_adam_lr1e-3.yaml

Other Implementations

Citation

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

@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}
}
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