This is the code repository implementing the paper:
MakeItTalk: Speaker-Aware Talking-Head Animation
Yang Zhou, Xintong Han, Eli Shechtman, Jose Echevarria , Evangelos Kalogerakis, Dingzeyu Li
SIGGRAPH Asia 2020
Abstract We present a method that generates expressive talking-head videos from a single facial image with audio as the only input. In contrast to previous attempts to learn direct mappings from audio to raw pixels for creating talking faces, our method first disentangles the content and speaker information in the input audio signal. The audio content robustly controls the motion of lips and nearby facial regions, while the speaker information determines the specifics of facial expressions and the rest of the talking-head dynamics. Another key component of our method is the prediction of facial landmarks reflecting the speaker-aware dynamics. Based on this intermediate representation, our method works with many portrait images in a single unified framework, including artistic paintings, sketches, 2D cartoon characters, Japanese mangas, and stylized caricatures. In addition, our method generalizes well for faces and characters that were not observed during training. We present extensive quantitative and qualitative evaluation of our method, in addition to user studies, demonstrating generated talking-heads of significantly higher quality compared to prior state-of-the-art methods.
[Project page] [Paper] [Video] [Arxiv] [Colab Demo] [Colab Demo TDLR]
Figure. Given an audio speech signal and a single portrait image as input (left), our model generates speaker-aware talking-head animations (right). Both the speech signal and the input face image are not observed during the model training process. Our method creates both non-photorealistic cartoon animations (top) and natural human face videos (bottom).
- Generate new puppet! (tested on Ubuntu)
- Pre-trained models
- Google colab quick demo for natural faces [detail] [TDLR]
- Training code for each module
- Python environment 3.6
conda create -n makeittalk_env python=3.6
conda activate makeittalk_env
- ffmpeg (https://ffmpeg.org/download.html)
sudo apt-get install ffmpeg
- python packages
pip install -r requirements.txt
winehq-stable
for cartoon face warping in Ubuntu (https://wiki.winehq.org/Ubuntu). Tested on Ubuntu16.04, wine==5.0.3.
sudo dpkg --add-architecture i386
wget -nc https://dl.winehq.org/wine-builds/winehq.key
sudo apt-key add winehq.key
sudo apt-add-repository 'deb https://dl.winehq.org/wine-builds/ubuntu/ xenial main'
sudo apt update
sudo apt install --install-recommends winehq-stable
Download the following pre-trained models to examples/ckpt
folder for testing your own animation.
Model | Link to the model |
---|---|
Voice Conversion | Link |
Speech Content Module | Link |
Speaker-aware Module | Link |
Image2Image Translation Module | Link |
Non-photorealistic Warping (.exe) | Link |
- Download pre-trained embedding [here] and save to
examples/dump
folder.
-
crop your portrait image into size
256x256
and put it underexamples
folder with.jpg
format. Make sure the head is almost in the middle (check existing examples for a reference). -
put test audio files under
examples
folder as well with.wav
format. -
animate!
python main_end2end.py --jpg <portrait_file>
- use addition args
--amp_lip_x <x> --amp_lip_y <y> --amp_pos <pos>
to amply lip motion (in x/y-axis direction) and head motion displacements, default values are<x>=2., <y>=2., <pos>=.5
-
put test audio files under
examples
folder as well with.wav
format. -
animate one of the existing puppets
Puppet Name | wilk | smiling_person | sketch | color | cartoonM | danbooru1 |
---|---|---|---|---|---|---|
Image |
python main_end2end_cartoon.py --jpg <cartoon_puppet_name_with_extension> --jpg_bg <puppet_background_with_extension>
-
--jpg_bg
takes a same-size image as the background image to create the animation, such as the puppet's body, the overall fixed background image. If you want to use the background, make sure the puppet face image (i.e.--jpg
image) is inpng
format and is transparent on the non-face area. If you don't need any background, please also create a same-size image (e.g. a pure white image) to hold the argument place. -
use addition args
--amp_lip_x <x> --amp_lip_y <y> --amp_pos <pos>
to amply lip motion (in x/y-axis direction) and head motion displacements, default values are<x>=2., <y>=2., <pos>=.5
-
put the cartoon image under
examples_cartoon
-
install conda environment
foa_env_py2
(tested on python 2) for Face-of-art (https://github.com/papulke/face-of-art). Download the pre-trained weight here and put it underexamples/ckpt
. Activate the environment.
source activate foa_env_py2
- create necessary files to animate your cartoon image, i.e.
<your_puppet>_open_mouth.txt
,<your_puppet>_close_mouth.txt
,<your_puppet>_open_mouth_norm.txt
,<your_puppet>_scale_shift.txt
,<your_puppet>_delauney.txt
python main_gen_new_puppet.py <your_puppet_with_file_extension>
-
in details, it takes 3 steps
- Face-of-art automatic cartoon landmark detection.
- If it's wrong or not accurate, you can use our tool to drag and refine the landmarks.
- Estimate the closed mouth landmarks to serve as network input.
- Delauney triangulate the image with landmarks.
-
check puppet name
smiling_person_example.png
for an example.
Landmark Adjustment Tool | Closed lips estimation | Delaunay Triangulation |
Todo...
-
Create dataset root directory
<root_dir>
-
Dataset: Download preprocessed dataset [here], and put it under
<root_dir>/dump
. -
Train script: Run script below. Models will be saved in
<root_dir>/ckpt/<train_instance_name>
.python main_train_content.py --train --write --root_dir <root_dir> --name <train_instance_name>
Todo...
Todo...
We would like to thank Timothy Langlois for the narration, and Kaizhi Qian for the help with the voice conversion module. We thank Jakub Fiser for implementing the real-time GPU version of the triangle morphing algorithm. We thank Daichi Ito for sharing the caricature image and Dave Werner for Wilk, the gruff but ultimately lovable puppet.
This research is partially funded by NSF (EAGER-1942069) and a gift from Adobe. Our experiments were performed in the UMass GPU cluster obtained under the Collaborative Fund managed by the MassTech Collaborative.