[ICCV '21] In this repository you find the code to our paper Keypoint Communities

Related tags

Deep Learning computer-vision deep-learning human-pose-estimation pose-estimation ms-coco ms-coco-keypoints coco-wholebody
Overview

Keypoint Communities

PWC PWC

In this repository you will find the code to our ICCV '21 paper:

Keypoint Communities
Duncan Zauss, Sven Kreiss, Alexandre Alahi, 2021.

We present a fast bottom-up method that jointly detects over 100 keypoints on humans or objects, also referred to as human/object pose estimation. We model all keypoints belonging to a human or an object -the pose- as a graph and leverage insights from community detection to quantify the independence of keypoints. We use a graph centrality measure to assign training weights to different parts of a pose. Our proposed measure quantifies how tightly a keypoint is connected to its neighborhood. Our experiments show that our method outperforms all previous methods for human pose estimation with fine-grained keypoint annotations on the face, the hands and the feet with a total of 133 keypoints. We also show that our method generalizes to car poses.

Qualitative results

example image with overlaid wholebody pose predictions

Image credit: Photo by Toby Bradbury which is licensed under CC-BY-2.0.

drawing

Webcam demo. You can try it out yourself with the following command:

python -m openpifpaf.video --checkpoint=shufflenetv2k16-wholebody --show --long-edge=320

example image with overlaid wholebody pose predictions

Image credit: Photo by Lokomotive74 which is licensed under CC-BY-4.0.
Created with:

python -m openpifpaf.predict docs/soccer.jpeg --checkpoint=shufflenetv2k30-wholebody --line-width=2 --show

example image with overlaid wholebody pose predictions

Image credit: "Learning to surf" by fotologic which is licensed under [CC-BY-2.0].
Created with:

python3 -m openpifpaf.predict docs/000000081988.jpg --checkpoint=shufflenetv2k30-wholebody --line-width=2 --show

Installation

This project is based on OpenPifPaf. Create a virtual environment with python 3.7, 3.8 or 3.9, clone this repo and then install the required packages:

git clone https://github.com/DuncanZauss/Keypoint_Communities.git
cd Keypoint_Communities
pip install -r requirements.txt

Obtain keypoint weights

To compute the keypoint weights with our method, download the preprocessed annotations of the MS COCO WholeBody dataset and/or the ApolloCar3D dataset with the following commands:

cd Keypoint_Communities/src
wget https://github.com/DuncanZauss/Keypoint_Communities/releases/download/v0.1.0/person_keypoints_train2017_wholebody_pifpaf_style.json
wget https://github.com/DuncanZauss/Keypoint_Communities/releases/download/v0.1.0/apollo_keypoints_66_train.json

To compute the average euclidean distance in the datasets for every edge run:

python Compute_edge_weights.py

To compute training weights with centrality measures as proposed in our paper run the following command:

python Compute_training_weights.py

You will find the computed weights in the respective csv file and a visualization of the computed weights in the respective docs folder.

Visualization of the weights for the WholeBody, where we take all shortest paths into account (left) and where we only take the shortest paths with a radius of three into account (right).

Visualization of the weights for the car pose, where we only take the shortest paths with a radius of three into account.

Training

For training you will need to download the MS COCO dataset and the WholeBody keypoint annotations as explained here. To train an OpenPifPaf model with our keypoint weighting scheme, you can use the following command:

python -m openpifpaf.train --dataset=wholebody --lr=0.0001 --momentum=0.95 --b-scale=10.0 --clip-grad-value=10 --epochs=350 --lr-decay 330 340 --lr-decay-epochs=10 --lr-warm-up-start-epoch=250 --batch-size=16 --weight-decay=1e-5 --wholebody-upsample=2 --wholebody-extended-scale --wholebody-orientation-invariant=0.1 --checkpoint=shufflenetv2k30 --head-consolidation=create --wholebody-val-annotations=
   
   
    
    /person_keypoints_val2017_wholebody_pifpaf_style.json --wholebody-train-annotations=
    
    
     
     /person_keypoints_train2017_wholebody_pifpaf_style.json --wholebody-apply-local-centrality-weights

Evaluation

To evaluate a trained model you first need to download the annotation file from this link and than you can use the following command to evaluate a model:

python -m openpifpaf.eval --dataset=wholebody --checkpoint=shufflenetv2k30-wholebody --force-complete-pose --seed-threshold=0.2 --force-complete-caf-th=0.001  --wholebody-val-annotations=
   
   
    
    /coco_wholebody_val_v1.0.json

The shufflenetv2k30-wholebody is our pretrained model, which was trained with the command from the Training section and will automatically be downloaded via torchhub. If you wish to evaluate your own model you can replace it with a local path to your model.

Related projects

Citation

If you find our research useful please cite us:

@misc{zauss2021keypoint,
      title={Keypoint Communities}, 
      author={Duncan Zauss and Sven Kreiss and Alexandre Alahi},
      year={2021},
      eprint={2110.00988},
      archivePrefix={arXiv},
      primaryClass={cs.CV}
}

License

The code in this repository is licensed under the MIT license. For more information please refer to the LICENSE file. This project is largely based on OpenPifPaf. OpenPifPaf is licensed under the GNU AGPLv3 license, for more information please refer to OpenPifPaf's license.

Comments
  • Weird prediction results on custom 24 kps car dataset

    Weird prediction results on custom 24 kps car dataset

    I have a dataset with 91 trannning & 9 validation images where 24 car kps are annotated and annotations are transformed to coco format as apollo where keypoints array is of size 24*3.

    I trained the shufflenetv2k16 24kps model. Trainning seems correct as shown below

    INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 1, 'batch': 0, 'n_batches': 18, 'time': 0.471, 'data_time': 4.657, 'lr': 2e-05, 'loss': 3540.623, 'head_losses': [3.702, 310.73, 0.799, 205.145, 3015.488, 4.761]}
INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 1, 'batch': 11, 'n_batches': 18, 'time': 0.434, 'data_time': 0.0, 'lr': 2e-05, 'loss': 3779.676, 'head_losses': [8.102, 372.573, 0.679, 149.955, 3243.949, 4.419]}
INFO:openpifpaf.network.trainer:applying ema
INFO:openpifpaf.network.trainer:{'type': 'train-epoch', 'epoch': 2, 'loss': 3874.88336, 'head_losses': [2.99886, 334.91886, 0.84728, 231.23997, 3298.75681, 6.1216], 'time': 14.2, 'n_clipped_grad': 0, 'max_norm': 0.0}
INFO:openpifpaf.network.trainer:restoring params from before ema

...

INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 100, 'batch': 0, 'n_batches': 18, 'time': 0.625, 'data_time': 2.206, 'lr': 2e-05, 'loss': 2648.88, 'head_losses': [-40.191, 469.212, 0.059, 123.052, 2095.671, 1.078]}
INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 100, 'batch': 11, 'n_batches': 18, 'time': 0.427, 'data_time': 0.0, 'lr': 2e-05, 'loss': 2616.817, 'head_losses': [-36.641, 429.025, 0.159, 120.99, 2102.774, 0.509]}
INFO:openpifpaf.network.trainer:applying ema
INFO:openpifpaf.network.trainer:{'type': 'train-epoch', 'epoch': 101, 'loss': 3276.90862, 'head_losses': [-45.2643, 351.73443, 0.60137, 196.80784, 2769.34305, 3.68621], 'time': 14.2, 'n_clipped_grad': 0, 'max_norm': 0.0}
INFO:openpifpaf.network.trainer:restoring params from before ema

...

INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 199, 'batch': 0, 'n_batches': 18, 'time': 0.46, 'data_time': 4.563, 'lr': 2e-06, 'loss': 3563.018, 'head_losses': [-61.656, 281.741, 0.614, 203.755, 3135.36, 3.203]}
INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 199, 'batch': 11, 'n_batches': 18, 'time': 0.435, 'data_time': 0.0, 'lr': 2e-06, 'loss': 3455.956, 'head_losses': [-54.041, 327.122, 0.471, 192.066, 2987.241, 3.097]}
INFO:openpifpaf.network.trainer:applying ema
INFO:openpifpaf.network.trainer:{'type': 'train-epoch', 'epoch': 200, 'loss': 3159.92377, 'head_losses': [-52.87015, 321.86455, 0.44325, 169.9907, 2718.06543, 2.42999], 'time': 20.8, 'n_clipped_grad': 0, 'max_norm': 0.0}
INFO:openpifpaf.network.trainer:model written: outputs/shufflenetv2k16-211021-024942-apollo.pkl.epoch200

...

INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 299, 'batch': 0, 'n_batches': 18, 'time': 0.614, 'data_time': 6.553, 'lr': 2e-07, 'loss': 3374.045, 'head_losses': [-54.347, 392.751, 0.522, 170.645, 2860.723, 3.751]}
INFO:openpifpaf.network.trainer:{'type': 'train', 'epoch': 299, 'batch': 11, 'n_batches': 18, 'time': 0.443, 'data_time': 0.0, 'lr': 2e-07, 'loss': 2769.724, 'head_losses': [-43.393, 481.309, 0.127, 131.402, 2198.701, 1.578]}
INFO:openpifpaf.network.trainer:applying ema
INFO:openpifpaf.network.trainer:{'type': 'train-epoch', 'epoch': 300, 'loss': 3054.62056, 'head_losses': [-52.68392, 345.90691, 0.38009, 155.51899, 2603.45154, 2.04698], 'time': 17.1, 'n_clipped_grad': 0, 'max_norm': 0.0}
INFO:openpifpaf.network.trainer:model written: outputs/shufflenetv2k16-211021-024942-apollo.pkl.epoch300

    However, all predictions are empty array.

    image

    The prediction codes are shown below

    import os
import numpy as np
from PIL import Image
import cv2
import openpifpaf

if __name__ == "__main__":

   src_img_folder = './images/train'
   dst_img_folder = './res/train'
   weights = './outputs/shufflenetv2k16-211021-024942-apollo.pkl.epoch200' 
 
   predictor = openpifpaf.Predictor(checkpoint=weights)

   img_names = os.listdir(src_img_folder)
   img_names = sorted(img_names)

   for name_idx,name_ in enumerate(img_names):

       I = Image.open(os.path.join(src_img_folder,name_)).convert('RGB')

       predictions, gt_anns, image_meta = predictor.pil_image(I)

       print(f"========== predictions: {predictions} ===============")
       print(f"========== image_meta: {image_meta} ==============")
    opened by KleinXin 9
  • Questions regarding the application of this paper/code.

    Questions regarding the application of this paper/code.

    Hello Thank you for the open-source code and great work! I had the following questions -

    1)Can we apply this code to a use-case as follows- A static camera is observing 2-3 moving robots in its FOV,and if I retrain the network with the images of the robot,with its corresponding ground-truth keypoints,the network can still predict the 2d keypoints of the moving robot right?

    2)For this does the robot have to be at a particular distance from the camera,so that the keypoint estimation is accurate enough?Meaning is the network's accuracy dependent on "the distance the object is from the camera"?

    3)Also can the network be used in a case where the camera observing the scene is moving as well as the object whose pose is to be estimated is also moving?Will the network's accuracy be effected in this case?

    Any suggestions/replies are greatly appreciated! Thank you

    opened by poornimajd 2
  • Running with multi-gpu or choosing a single gpu for inference

    Running with multi-gpu or choosing a single gpu for inference

    I can't seem to get this to run in a multi-gpu enviroment. I've tried setting the export CUDA_VISIBLE_DEVICES=0 in my bash enviroment but that didn't seem to do the trick. Any help is appreciated!

    opened by pablovela5620 2
  • Prediction result for soccer.jpeg is not as good as the shown image

    Prediction result for soccer.jpeg is not as good as the shown image

    Screenshot from 2021-11-09 23-33-13 I use the same command 'python -m openpifpaf.predict docs/soccer.jpeg --checkpoint=shufflenetv2k30-wholebody --line-width=2 --show ' to run the prediction but the hands of the front person are not aligned as your shown image. Did you use a different weight? Or is there any other problems?

    opened by Kairobo 1
  • Issues running webcam/videos

    Issues running webcam/videos

    Getting the following errors when trying to use on webcam or video source

    (kc) pablo@pablo-Alienware-Aurora-R7:~/0Dev/Keypoint_Communities$ python -m openpifpaf.video --source ../immersed-ganerated/data/iterim/test_vid3.webm --checkpoint=shufflenetv2k30-wholebody --line-width=2 --showINFO:__main__:neural network device: cuda (CUDA available: True, count: 1)
INFO:openpifpaf.decoder.factory:No specific decoder requested. Using the first one from:
  --decoder=cifcaf:0
  --decoder=posesimilarity:0
Use any of the above arguments to select one or multiple decoders and to suppress this message.
INFO:openpifpaf.predictor:neural network device: cuda (CUDA available: True, count: 1)
INFO:openpifpaf.show.animation_frame:video output = None
Traceback (most recent call last):
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/runpy.py", line 194, in _run_module_as_main
    return _run_code(code, main_globals, None,
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/runpy.py", line 87, in _run_code
    exec(code, run_globals)
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/openpifpaf/video.py", line 158, in <module>
    main()
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/openpifpaf/video.py", line 129, in main
    for (ax, ax_second), (preds, _, meta) in \
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/openpifpaf/predictor.py", line 112, in dataset
    yield from self.dataloader(dataloader)
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/openpifpaf/predictor.py", line 149, in dataloader
    yield from self.enumerated_dataloader(enumerate(dataloader))
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/openpifpaf/predictor.py", line 115, in enumerated_dataloader
    for batch_i, item in enumerated_dataloader:
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/torch/utils/data/dataloader.py", line 521, in __next__
    data = self._next_data()
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/torch/utils/data/dataloader.py", line 1203, in _next_data
    return self._process_data(data)
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/torch/utils/data/dataloader.py", line 1229, in _process_data
    data.reraise()
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/torch/_utils.py", line 425, in reraise
    raise self.exc_type(msg)
AttributeError: Caught AttributeError in DataLoader worker process 0.
Original Traceback (most recent call last):
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/torch/utils/data/_utils/worker.py", line 287, in _worker_loop
    data = fetcher.fetch(index)
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/torch/utils/data/_utils/fetch.py", line 28, in fetch
    data.append(next(self.dataset_iter))
  File "/home/pablo/miniconda3/envs/kc/lib/python3.8/site-packages/openpifpaf/stream.py", line 119, in __iter__
    capture = cv2.VideoCapture(self.source)
AttributeError: 'NoneType' object has no attribute 'VideoCapture'

    I have no problem running the demo on images as shown in the readme, its only with videos

    opened by pablovela5620 1
  • Common model for human and car keypoint

    Common model for human and car keypoint

    HI, thanks for sharing! Can you please elaborate more, in your second demo video we can see you detected human and vehicle key points in each frame? Was it two different models of a single model? If it is a single model please let me know where to get it. Thank you in advance.

    opened by capslocknanda 1
  • can't run the demo

    can't run the demo

    Hi there, I can't run the webcam and the demo with image source either. Not sure what's happening.

    Working Environment 
OS: macOS 12.1 21C52 x86_64 
Host: iMac19,1
Kernel: 21.2.0
CPU: Intel i5-8500 (6) @ 3.00GHz
GPU: Radeon Pro 570X

    I used miniconda to install this repo. Not sure whether it needs cuda support

    opened by yktangac 4
  • PytorchStreamReader failed reading zip archive: failed finding central directory

    PytorchStreamReader failed reading zip archive: failed finding central directory

    When i run the demo, i meet the error like this:

    INFO:__main__:neural network device: cuda (CUDA available: True, count: 2)
Traceback (most recent call last):
  File "/root/miniconda3/envs/key_com/lib/python3.8/runpy.py", line 192, in _run_module_as_main
    return _run_code(code, main_globals, None,
  File "/root/miniconda3/envs/key_com/lib/python3.8/runpy.py", line 85, in _run_code
    exec(code, run_globals)
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/openpifpaf/predict.py", line 128, in <module>
    main()
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/openpifpaf/predict.py", line 103, in main
    predictor = Predictor(
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/openpifpaf/predictor.py", line 29, in __init__
    self.model_cpu, _ = network.Factory().factory(head_metas=head_metas)
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/openpifpaf/network/factory.py", line 302, in factory
    net_cpu, epoch = self.from_checkpoint()
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/openpifpaf/network/factory.py", line 366, in from_checkpoint
    checkpoint = torch.hub.load_state_dict_from_url(
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/torch/hub.py", line 590, in load_state_dict_from_url
    return torch.load(cached_file, map_location=map_location)
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/torch/serialization.py", line 600, in load
    with _open_zipfile_reader(opened_file) as opened_zipfile:
  File "/root/miniconda3/envs/key_com/lib/python3.8/site-packages/torch/serialization.py", line 242, in __init__
    super(_open_zipfile_reader, self).__init__(torch._C.PyTorchFileReader(name_or_buffer))
RuntimeError: PytorchStreamReader failed reading zip archive: failed finding central directory

    My torch version is 1.10.0.

    opened by sulei1998 2
  • Problems during operation

    Problems during operation

    Hello author, I'm trying to re-implement your code, but in the process, I'm encountering problems. First I need to state that I successfully installed the environment and ran the steps: python Compute_edge_weights.py Secondly, After running this command (python Compute_training_weights.py) the following error is reported:

    Traceback (most recent call last): File "/home/hcb/Keypoint_Communities/src/Compute_training_weights.py", line 314, in create_weights_wholebody() File "/home/hcb/Keypoint_Communities/src/Compute_training_weights.py", line 192, in create_weights_wholebody draw_skeletons_wb(WHOLEBODY_STANDING_POSE, inverse_normalize(w_harm_cl_euclid, kps=kps), File "/home/hcb/Keypoint_Communities/src/Compute_training_weights.py", line 60, in draw_skeletons_wb from openpifpaf.annotation import Annotation # pylint: disable=import-outside-toplevel File "/home/hcb/anaconda3/envs/keypoint/lib/python3.8/site-packages/openpifpaf/init.py", line 11, in cpp_extension.register_ops() File "/home/hcb/anaconda3/envs/keypoint/lib/python3.8/site-packages/openpifpaf/cpp_extension.py", line 26, in register_ops torch.ops.load_library(ext_specs.origin) File "/home/hcb/anaconda3/envs/keypoint/lib/python3.8/site-packages/torch/_ops.py", line 104, in load_library ctypes.CDLL(path) File "/home/hcb/anaconda3/envs/keypoint/lib/python3.8/ctypes/init.py", line 373, in init self._handle = _dlopen(self._name, mode) OSError: /home/hcb/anaconda3/envs/keypoint/lib/python3.8/site-packages/openpifpaf/_cpp.so: undefined symbol: ZN5torch6detail10class_baseC2ERKSsS3_SsRKSt9type_infoS6 directory

    (I only changed the path, no other code was touched. The code can generate a folder named docs_wb, but it is empty.My directory is shown in the figure)

    cheers

    opened by hechengbo-H 2
  • Error while installing openpifpaf

    Error while installing openpifpaf

    While running the requirements.txt I got stuck on an issue regarding openpifpaf==0.13.0. It seems like the version cannot be found. Do you have a way to bypass that ?

    opened by samymdihi 4
Owner
Duncan Zauss
Duncan Zauss
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The dataset and source code for our paper: "Did You Ask a Good Question? A Cross-Domain Question IntentionClassification Benchmark for Text-to-SQL"

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Source Code for our paper: Understand me, if you refer to Aspect Knowledge: Knowledge-aware Gated Recurrent Memory Network

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