tf-pose-estimation
'Openpose' for human pose estimation have been implemented using Tensorflow. It also provides several variants that have made some changes to the network structure for real-time processing on the CPU or low-power embedded devices.
You can even run this on your macbook with descent FPS!
Original Repo(Caffe) : https://github.com/CMU-Perceptual-Computing-Lab/openpose
Implemented features are listed here : features
Important Updates
2018.5.21 Post-processing part is implemented in c++. It is required compiling the part. See: https://github.com/ildoonet/tf-pose-estimation/tree/master/src/pafprocess 2018.2.7 Arguments in run.py script changed. Support dynamic input size.
Install
Dependencies
You need dependencies below.
- python3
- tensorflow 1.4.1+
- opencv3, protobuf, python3-tk
Opensources
- slim
- slidingwindow
- https://github.com/adamrehn/slidingwindow
- I copied from the above git repo to modify few things.
Install
Clone the repo and install 3rd-party libraries.
$ git clone https://www.github.com/ildoonet/tf-openpose
$ cd tf-openpose
$ pip3 install -r requirements.txt
Build c++ library for post processing. See : https://github.com/ildoonet/tf-pose-estimation/tree/master/tf_pose/pafprocess
$ cd tf_pose/pafprocess
$ swig -python -c++ pafprocess.i && python3 setup.py build_ext --inplace
Package Install
Alternatively, you can install this repo as a shared package using pip.
$ git clone https://www.github.com/ildoonet/tf-openpose
$ cd tf-openpose
$ python setup.py install
Test installed package
python -c 'import tf_pose; tf_pose.infer(image="./images/p1.jpg")'
Models
I have tried multiple variations of models to find optmized network architecture. Some of them are below and checkpoint files are provided for research purpose.
-
cmu
- the model based VGG pretrained network which described in the original paper.
- I converted Weights in Caffe format to use in tensorflow.
- pretrained weight download
-
dsconv
- Same architecture as the cmu version except for the depthwise separable convolution of mobilenet.
- I trained it using 'transfer learning', but it provides not-enough speed and accuracy.
-
mobilenet
- Based on the mobilenet paper, 12 convolutional layers are used as feature-extraction layers.
- To improve on small person, minor modification on the architecture have been made.
- Three models were learned according to network size parameters.
- mobilenet
- 368x368 : checkpoint weight download
- mobilenet_fast
- mobilenet_accurate
- mobilenet
- I published models which is not the best ones, but you can test them before you trained a model from the scratch.
Download Tensorflow Graph File(pb file)
Before running demo, you should download graph files. You can deploy this graph on your mobile or other platforms.
- cmu (trained in 656x368)
- mobilenet_thin (trained in 432x368)
CMU's model graphs are too large for git, so I uploaded them on an external cloud. You should download them if you want to use cmu's original model. Download scripts are provided in the model folder.
$ cd models/graph/cmu
$ bash download.sh
Inference Time
Dataset | Model | Inference Time Macbook Pro i5 3.1G |
Inference Time Jetson TX2 |
---|---|---|---|
Coco | cmu | 10.0s @ 368x368 | OOM @ 368x368 5.5s @ 320x240 |
Coco | dsconv | 1.10s @ 368x368 | |
Coco | mobilenet_accurate | 0.40s @ 368x368 | 0.18s @ 368x368 |
Coco | mobilenet | 0.24s @ 368x368 | 0.10s @ 368x368 |
Coco | mobilenet_fast | 0.16s @ 368x368 | 0.07s @ 368x368 |
Demo
Test Inference
You can test the inference feature with a single image.
$ python run.py --model=mobilenet_thin --resize=432x368 --image=./images/p1.jpg
The image flag MUST be relative to the src folder with no "~", i.e:
--image ../../Desktop
Then you will see the screen as below with pafmap, heatmap, result and etc.
Realtime Webcam
$ python run_webcam.py --model=mobilenet_thin --resize=432x368 --camera=0
Then you will see the realtime webcam screen with estimated poses as below. This Realtime Result was recored on macbook pro 13" with 3.1Ghz Dual-Core CPU.
Python Usage
This pose estimator provides simple python classes that you can use in your applications.
See run.py or run_webcam.py as references.
e = TfPoseEstimator(get_graph_path(args.model), target_size=(w, h))
humans = e.inference(image)
image = TfPoseEstimator.draw_humans(image, humans, imgcopy=False)
ROS Support
See : etcs/ros.md
Training
See : etcs/training.md
References
OpenPose
[1] https://github.com/CMU-Perceptual-Computing-Lab/openpose
[2] Training Codes : https://github.com/ZheC/Realtime_Multi-Person_Pose_Estimation
[3] Custom Caffe by Openpose : https://github.com/CMU-Perceptual-Computing-Lab/caffe_train
[4] Keras Openpose : https://github.com/michalfaber/keras_Realtime_Multi-Person_Pose_Estimation
[5] Keras Openpose2 : https://github.com/kevinlin311tw/keras-openpose-reproduce
Lifting from the deep
[1] Arxiv Paper : https://arxiv.org/abs/1701.00295
[2] https://github.com/DenisTome/Lifting-from-the-Deep-release
Mobilenet
[1] Original Paper : https://arxiv.org/abs/1704.04861
[2] Pretrained model : https://github.com/tensorflow/models/blob/master/slim/nets/mobilenet_v1.md
Libraries
[1] Tensorpack : https://github.com/ppwwyyxx/tensorpack
Tensorflow Tips
[1] Freeze graph : https://github.com/tensorflow/tensorflow/blob/master/tensorflow/python/tools/freeze_graph.py
[2] Optimize graph : https://codelabs.developers.google.com/codelabs/tensorflow-for-poets-2