Skip to content

Implementation of Auto-Conditioned Recurrent Networks for Extended Complex Human Motion Synthesis

License

Notifications You must be signed in to change notification settings

B-Step62/Auto_Conditioned_RNN_motion

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

7 Commits
 
 
 
 
 
 
 
 

Repository files navigation

acLSTM_motion

This folder contains an implementation of acRNN for the CMU motion database written in Pytorch.

See the following links for more background:

Auto-Conditioned Recurrent Networks for Extended Complex Human Motion Synthesis

CMU Motion Capture Database

Prequisite

You need to install python3.6 (python 2.7 should also be fine) and pytorch. You will also need to have transforms3d, which can be installed by using this command:

pip install transforms3d

Data Preparation

To begin, you need to download the motion data form the CMU motion database in the form of bvh files. I have already put some sample bvh files including "salsa", "martial" and "indian" in the "train_data_bvh" folder.

Then to transform the bvh files into training data, go to the folder "code" and run generate_training_data.py. You will need to change the directory of the source motion folder and the target motioin folder on the last line. If you don't change anything, this code will create a directory "../train_data_xyz/indian" and generate the training data for indian dances in this folder.

Training

After generating the training data, you can start to train the network by running the pytorch_train_aclstm.py. Again, you need to change some directories on the last few lines in the code, including "dances_folder" which is the location of the training data, "write_weight_folder" which is the location to save the weights of the network during training, "write_bvh_motion_folder" which is the location to save the temporate output of the network and the groundtruth motion sequences in the form of bvh, and "read_weight_path" which is the path of the network weights if you want to train the network from some pretrained weights other than from begining in which case it is set as "". If you don't change anything, this code will train the network upon the indian dance data and create two folders ("../train_weight_aclstm_indian/" and "../train_tmp_bvh_aclstm_indian/") to save the weights and temporate outputs.

Testing

When the training is done, you can use pytorch_test_synthesize_motion.py to synthesize motions. You will need to change the last few lines to set the "read_weight_path" which is the location of the weights of the network you want to test, "write_bvh_motion_folder" which is the location of the output motions, "dances_folder" is the where the code randomly picked up a short initial sequence from. You may also want to set the "batch" to determine how many motion clips you want to generate, the "generate_frames_numbers" to determine the length of the motion clips et al.. If you don't change anything, the code will read the weights from the 86000th iteration and generate 5 indian dances in the form of bvh to "../test_bvh_aclstm_indian/".

The output motions from the network usually have artifacts of sliding feet and sometimes underneath-ground feet. If you are not satisfied with these details, you can use fix_feet.py to solve it. The algorithm in this code is very simple and you are welcome to write a more complex version that can preserve the kinematics of the human body and share it to us.

For rendering the bvh motion, you can use softwares like MotionBuilder, Maya, 3D max or most easily, use an online BVH renderer for example: http://lo-th.github.io/olympe/BVH_player.html

Enjoy!

About

Implementation of Auto-Conditioned Recurrent Networks for Extended Complex Human Motion Synthesis

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Python 100.0%