By Weiyang Liu, Yandong Wen, Zhiding Yu, Ming Li, Bhiksha Raj and Le Song
SphereFace is released under the MIT License (refer to the LICENSE file for details).
- Introduction
- Citation
- Requirements
- Installation
- Usage
- Models
- Results
- Video Demo
- Note
- Third-party re-implementation
The repository contains the entire pipeline (including all the preprocessings) for deep face recognition with SphereFace
. The recognition pipeline contains three major steps: face detection, face alignment and face recognition.
SphereFace is a recently proposed face recognition method. It was initially described in an arXiv technical report and then published in CVPR 2017. To facilitate the face recognition research, we give an example of training on CAISA-WebFace and testing on LFW using the 20-layer CNN architecture described in the paper (i.e. SphereFace-20).
In SphereFace, our network architecures use residual units as building blocks, but are quite different from the standrad ResNets (e.g., BatchNorm is not used, the prelu replaces the relu, different initializations, etc). We proposed 4-layer, 20-layer, 36-layer and 64-layer architectures for face recognition (details can be found in the paper and prototxt files). We provided the 20-layer architecure as an example here. If our proposed architectures also help your research, please consider to cite our paper.
SphereFace achieves the state-of-the-art verification performance (previously No.1) in MegaFace Challenge under the small training set protocol.
If you find SphereFace useful in your research, please consider to cite:
@InProceedings{Liu_2017_CVPR,
title = {SphereFace: Deep Hypersphere Embedding for Face Recognition},
author = {Liu, Weiyang and Wen, Yandong and Yu, Zhiding and Li, Ming and Raj, Bhiksha and Song, Le},
booktitle = {The IEEE Conference on Computer Vision and Pattern Recognition (CVPR)},
year = {2017}
}
Our another closely-related previous work in ICML'16 (more):
@InProceedings{Liu_2016_ICML,
title = {Large-Margin Softmax Loss for Convolutional Neural Networks},
author = {Liu, Weiyang and Wen, Yandong and Yu, Zhiding and Yang, Meng},
booktitle = {Proceedings of The 33rd International Conference on Machine Learning},
year = {2016}
}
- Requirements for
Matlab
- Requirements for
Caffe
andmatcaffe
(see: Caffe installation instructions) - Requirements for
MTCNN
(see: MTCNN - face detection & alignment) andPdollar toolbox
(see: Piotr's Image & Video Matlab Toolbox).
-
Clone the SphereFace repository. We'll call the directory that you cloned SphereFace as
SPHEREFACE_ROOT
.git clone --recursive https://github.com/wy1iu/sphereface.git
-
Build Caffe and matcaffe
cd $SPHEREFACE_ROOT/tools/caffe-sphereface # Now follow the Caffe installation instructions here: # http://caffe.berkeleyvision.org/installation.html make all -j8 && make matcaffe
After successfully completing the installation, you are ready to run all the following experiments.
Note: In this part, we assume you are in the directory $SPHEREFACE_ROOT/preprocess/
-
Download the training set (
CASIA-WebFace
) and test set (LFW
) and place them indata/
.mv /your_path/CASIA_WebFace data/ ./code/get_lfw.sh tar xvf data/lfw.tgz -C data/
Please make sure that the directory of
data/
contains two datasets. -
Detect faces and facial landmarks in CAISA-WebFace and LFW datasets using
MTCNN
(see: MTCNN - face detection & alignment).# In Matlab Command Window run code/face_detect_demo.m
This will create a file
dataList.mat
in the directory ofresult/
. -
Align faces to a canonical pose using similarity transformation.
# In Matlab Command Window run code/face_align_demo.m
This will create two folders (
CASIA-WebFace-112X96/
andlfw-112X96/
) in the directory ofresult/
, containing the aligned face images.
Note: In this part, we assume you are in the directory $SPHEREFACE_ROOT/train/
-
Get a list of training images and labels.
mv ../preprocess/result/CASIA-WebFace-112X96 data/ # In Matlab Command Window run code/get_list.m
The aligned face images in folder
CASIA-WebFace-112X96/
are moved from preprocess folder to train folder. A listCASIA-WebFace-112X96.txt
is created in the directory ofdata/
for the subsequent training. -
Train the sphereface model.
./code/sphereface/sphereface_train.sh 0,1
After training, a model
sphereface_model_iter_28000.caffemodel
and a corresponding log filesphereface_train.log
are placed in the directory ofresult/sphereface/
.
Note: In this part, we assume you are in the directory $SPHEREFACE_ROOT/test/
-
Get the pair list of LFW (view 2).
mv ../preprocess/result/lfw-112X96 data/ ./code/get_pairs.sh
Make sure that the LFW dataset and
pairs.txt
in the directory ofdata/
-
Extract deep features and test on LFW.
# In Matlab Command Window run code/evaluation.m
Finally we have the
sphereface_model.caffemodel
, extracted featurespairs.mat
in folderresult/
, and accuracy on LFW like this:fold 1 2 3 4 5 6 7 8 9 10 AVE ACC 99.33% 99.17% 98.83% 99.50% 99.17% 99.83% 99.17% 98.83% 99.83% 99.33% 99.30%
- Visualizations of network architecture (tools from ethereon):
- SphereFace-20: link
- Model file
- SphereFace-20: Google Drive | Baidu
-
Following the instruction, we go through the entire pipeline for 5 times. The accuracies on LFW are shown below. Generally, we report the average but we release the model-3 here.
Experiment #1 #2 #3 (released) #4 #5 ACC 99.24% 99.20% 99.30% 99.27% 99.13% -
Other intermediate results:
- LFW features: Google Drive | Baidu
- Training log: Google Drive | Baidu
Please click the image to watch the Youtube video. For Youku users, click here.
Details:
- It is an open-set face recognition scenario. The video is processed frame by frame, following the same pipeline in this repository.
- Gallery set consists of 6 identities. Each main character has only 1 gallery face image. All the detected faces are included in probe set.
- There is no overlap between gallery set and training set (CASIA-WebFace).
- The scores between each probe face and gallery set are computed by cosine similarity. If the maximal score of a probe face is smaller than a pre-definded threshold, the probe face would be considered as an outlier.
- Main characters are labeled by boxes with different colors. ( Rachel, Monica, Phoebe, Joey, Chandler, Ross)
-
Backward gradient
- In this implementation, we did not strictly follow the equations in paper. Instead, we normalize the scale of gradient. It can be interpreted as a varying strategy for learning rate to help converge more stably. Similar idea and intuition also appear in normalized gradients and projected gradient descent.
- More specifically, if the original gradient of f w.r.t x can be written as df/dx = coeff_w * w + coeff_x * x, we use the normalized version [df/dx] = (coeff_w * w + coeff_x * x) / norm_wx to perform backward propragation, where norm_wx is sqrt(coeff_w^2 + coeff_x^2). The same operation is also applied to the gradient of f w.r.t w.
- In fact, you do not necessarily need to use the original gradient, since the original gradient sometimes is not an optimal design. One important criterion for modifying the backprop gradient is that the new "gradient" (strictly speaking, it is not a gradient anymore) need to make the objective value decrease stably and consistently. (In terms of some failure cases for gradient-based back-prop, I recommand a great talk by Shai Shalev-Shwartz)
- If you use the original gradient to do the backprop, you could still make it work but may need different lambda settings, iteration number and learning rate decay strategy.
-
Lambda and Note for training (When the loss becomes 87)
- Please refer to our previous note and explanation.
- PyTorch: code by clcarwin.
- TensorFlow: code by pppoe.
- TensorFlow: code by hujun100.
- Caffe2: code by tpys.
- Trained on MS-1M: code by KaleidoZhouYN.
- System: A cool face demo system using SphereFace by tpys.
- Third-party pretrained models: code by goodluckcwl
Questions can also be left as issues in the repository. We will be happy to answer them.