The repository builds on Daniil Osokin's Lightweight OpenPose in PyTorch with basic stability analysis. This is tested for CPU only, although GPU and OpenVINO should work as well. Please refer to repo documentation to set up - requirements.txt here has been updated to fix dependency issues. I am exploring ways to wrap dependencies in a Vagrant container.
Link to download training checkpoint (thanks to Daniil Osokin): https://download.01.org/opencv/openvino_training_extensions/models/human_pose_estimation/checkpoint_iter_370000.pth
If this helps your research, please cite Daniil's paper:
@inproceedings{osokin2018lightweight_openpose,
author={Osokin, Daniil},
title={Real-time 2D Multi-Person Pose Estimation on CPU: Lightweight OpenPose},
booktitle = {arXiv preprint arXiv:1811.12004},
year = {2018}
}
This repository contains training code for the paper Real-time 2D Multi-Person Pose Estimation on CPU: Lightweight OpenPose. This work heavily optimizes the OpenPose approach to reach real-time inference on CPU with negliable accuracy drop. It detects a skeleton (which consists of keypoints and connections between them) to identify human poses for every person inside the image. The pose may contain up to 18 keypoints: ears, eyes, nose, neck, shoulders, elbows, wrists, hips, knees, and ankles. On COCO 2017 Keypoint Detection validation set this code achives 40% AP for the single scale inference (no flip or any post-processing done). The result can be reproduced using this repository. This repo significantly overlaps with https://github.com/opencv/openvino_training_extensions, however contains just the necessary code for human pose estimation.
🔥 Check out our new work on accurate (and still fast) single-person pose estimation, which ranked 10th on CVPR'19 Look-Into-Person challenge.
🔥🔥 Check out our lightweight 3D pose estimation, which is based on Single-Shot Multi-Person 3D Pose Estimation From Monocular RGB paper and this work.
- TensorFlow by murdockhou.
- Ubuntu 16.04
- Python 3.6
- PyTorch 0.4.1 (should also work with 1.0, but not tested)
- Download COCO 2017 dataset: http://cocodataset.org/#download (train, val, annotations) and unpack it to
<COCO_HOME>
folder. - Install requirements
pip install -r requirements.txt
Training consists of 3 steps (given AP values for full validation dataset):
- Training from MobileNet weights. Expected AP after this step is ~38%.
- Training from weights, obtained from previous step. Expected AP after this step is ~39%.
- Training from weights, obtained from previous step and increased number of refinement stages to 3 in network. Expected AP after this step is ~40% (for the network with 1 refinement stage, two next are discarded).
-
Download pre-trained MobileNet v1 weights
mobilenet_sgd_68.848.pth.tar
from: https://github.com/marvis/pytorch-mobilenet (sgd option). If this doesn't work, download from GoogleDrive. -
Convert train annotations in internal format. Run
python scripts/prepare_train_labels.py --labels <COCO_HOME>/annotations/person_keypoints_train2017.json
. It will produceprepared_train_annotation.pkl
with converted in internal format annotations.[OPTIONAL] For fast validation it is recommended to make subset of validation dataset. Run
python scripts/make_val_subset.py --labels <COCO_HOME>/annotations/person_keypoints_val2017.json
. It will produceval_subset.json
with annotations just for 250 random images (out of 5000). -
To train from MobileNet weights, run
python train.py --train-images-folder <COCO_HOME>/train2017/ --prepared-train-labels prepared_train_annotation.pkl --val-labels val_subset.json --val-images-folder <COCO_HOME>/val2017/ --checkpoint-path <path_to>/mobilenet_sgd_68.848.pth.tar --from-mobilenet
-
Next, to train from checkpoint from previous step, run
python train.py --train-images-folder <COCO_HOME>/train2017/ --prepared-train-labels prepared_train_annotation.pkl --val-labels val_subset.json --val-images-folder <COCO_HOME>/val2017/ --checkpoint-path <path_to>/checkpoint_iter_420000.pth --weights-only
-
Finally, to train from checkpoint from previous step and 3 refinement stages in network, run
python train.py --train-images-folder <COCO_HOME>/train2017/ --prepared-train-labels prepared_train_annotation.pkl --val-labels val_subset.json --val-images-folder <COCO_HOME>/val2017/ --checkpoint-path <path_to>/checkpoint_iter_280000.pth --weights-only --num-refinement-stages 3
. We took checkpoint after 370000 iterations as the final one.
We did not perform the best checkpoint selection at any step, so similar result may be achieved after less number of iterations.
We observe this error with maximum number of open files (ulimit -n
) equals to 1024:
File "train.py", line 164, in <module>
args.log_after, args.val_labels, args.val_images_folder, args.val_output_name, args.checkpoint_after, args.val_after)
File "train.py", line 77, in train
for _, batch_data in enumerate(train_loader):
File "/<path>/python3.6/site-packages/torch/utils/data/dataloader.py", line 330, in __next__
idx, batch = self._get_batch()
File "/<path>/python3.6/site-packages/torch/utils/data/dataloader.py", line 309, in _get_batch
return self.data_queue.get()
File "/<path>/python3.6/multiprocessing/queues.py", line 337, in get
return _ForkingPickler.loads(res)
File "/<path>/python3.6/site-packages/torch/multiprocessing/reductions.py", line 151, in rebuild_storage_fd
fd = df.detach()
File "/<path>/python3.6/multiprocessing/resource_sharer.py", line 58, in detach
return reduction.recv_handle(conn)
File "/<path>/python3.6/multiprocessing/reduction.py", line 182, in recv_handle
return recvfds(s, 1)[0]
File "/<path>/python3.6/multiprocessing/reduction.py", line 161, in recvfds
len(ancdata))
RuntimeError: received 0 items of ancdata
To get rid of it, increase the limit to bigger number, e.g. 65536, run in the terminal: ulimit -n 65536
- Run
python val.py --labels <COCO_HOME>/annotations/person_keypoints_val2017.json --images-folder <COCO_HOME>/val2017 --checkpoint-path <CHECKPOINT>
The model expects normalized image (mean=[128, 128, 128], scale=[1/256, 1/256, 1/256]) in planar BGR format. Pre-trained on COCO model is available at: https://download.01.org/opencv/openvino_training_extensions/models/human_pose_estimation/checkpoint_iter_370000.pth, it has 40% of AP on COCO validation set (38.6% of AP on the val subset).
- Convert PyTorch model to ONNX format: run script in terminal
python scripts/convert_to_onnx.py --checkpoint-path <CHECKPOINT>
. It produceshuman-pose-estimation.onnx
. - Convert ONNX model to OpenVINO format with Model Optimizer: run in terminal
python <OpenVINO_INSTALL_DIR>/deployment_tools/model_optimizer/mo.py --input_model human-pose-estimation.onnx --input data --mean_values data[128.0,128.0,128.0] --scale_values data[256] --output stage_1_output_0_pafs,stage_1_output_1_heatmaps
. This produces modelhuman-pose-estimation.xml
and weightshuman-pose-estimation.bin
in single-precision floating-point format (FP32).
To run the demo download Intel® OpenVINO™ Toolkit https://software.intel.com/en-us/openvino-toolkit/choose-download, install it and build the samples (Inferring Your Model with the Inference Engine Samples part). Then run <SAMPLES_BIN_FOLDER>/human_pose_estimation_demo -m <path_to>/human-pose-estimation.xml -i <path_to_video_file>
for the inference on CPU
.
We provide python demo just for the quick results preview. Please, consider c++ demo for the best performance. To run the python demo from a webcam:
python demo.py --checkpoint-path <path_to>/checkpoint_iter_370000.pth --video 0