Skip to content

GRAYKEY/insightface

 
 

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

InsightFace: 2D and 3D Face Analysis Project

By Jia Guo and Jiankang Deng

License

The code of InsightFace is released under the MIT License.

Recent Update

2018.04.23: Our implementation of MobileFaceNets is now available. Please check Training section for more detail on how to use this lightweight but powerful network backbone.

2018.03.26: We can train with combined margin(loss-type=5), see Verification Results On Combined Margin.

2018.02.13: We achieved state-of-the-art performance on MegaFace-Challenge. Please check our paper and code for implementation details.

Contents

Deep Face Recognition

Face Alignment

Face Detection

Citation

Contact

Deep Face Recognition

Introduction

In this repository, we provide training data, network settings and loss designs for deep face recognition. The training data includes the normalised MS1M and VGG2 datasets, which were already packed in the MxNet binary format. The network backbones include ResNet, InceptionResNet_v2, DenseNet, DPN and MobiletNet. The loss functions include Softmax, SphereFace, CosineFace, ArcFace and Triplet (Euclidean/Angular) Loss.

  • loss-type=0: Softmax
  • loss-type=1: SphereFace
  • loss-type=2: CosineFace
  • loss-type=4: ArcFace
  • loss-type=5: Combined Margin
  • loss-type=12: TripletLoss

margin penalty for target logit

Our method, ArcFace, was initially described in an arXiv technical report. By using this repository, you can simply achieve LFW 99.80%+ and Megaface 98%+ by a single model. This repository can help researcher/engineer to develop deep face recognition algorithms quickly by only two steps: download the binary dataset and run the training script.

Training Data

All face images are aligned by MTCNN and cropped to 112x112:

Note: If you use the refined MS1M dataset and the cropped VGG2 dataset, please cite the original papers.

Train

  1. Install MXNet with GPU support (Python 2.7).
pip install mxnet-cu80
  1. Clone the InsightFace repository. We call the directory insightface as INSIGHTFACE_ROOT.
git clone --recursive https://github.com/deepinsight/insightface.git
  1. Download the training set (MS1M) and place it in $INSIGHTFACE_ROOT/datasets/. Each training dataset includes following 7 files:
    faces_ms1m_112x112/
       train.idx
       train.rec
       property
       lfw.bin
       cfp_ff.bin
       cfp_fp.bin
       agedb_30.bin

The first three files are the training dataset while the last four files are verification sets.

  1. Train deep face recognition models. In this part, we assume you are in the directory $INSIGHTFACE_ROOT/src/.
export MXNET_CPU_WORKER_NTHREADS=24
export MXNET_ENGINE_TYPE=ThreadedEnginePerDevice

We give some examples below. Our experiments were conducted on the Tesla P40 GPU.

(1). Train ArcFace with LResNet100E-IR.

CUDA_VISIBLE_DEVICES='0,1,2,3' python -u train_softmax.py --network r100 --loss-type 4 --margin-m 0.5 --data-dir ../datasets/faces_ms1m_112x112  --prefix ../model-r100

It will output verification results of LFW, CFP-FF, CFP-FP and AgeDB-30 every 2000 batches. You can check all command line options in train_softmax.py. This model can achieve LFW 99.80+ and MegaFace 98.0%+.

(2). Train CosineFace with LResNet50E-IR.

CUDA_VISIBLE_DEVICES='0,1,2,3' python -u train_softmax.py --network r50 --loss-type 2 --margin-m 0.35 --data-dir ../datasets/faces_ms1m_112x112 --prefix ../model-r50-amsoftmax

(3). Train Softmax with LMobileNetE.

CUDA_VISIBLE_DEVICES='0,1,2,3' python -u train_softmax.py --network m1 --loss-type 0 --data-dir ../datasets/faces_ms1m_112x112 --prefix ../model-m1-softmax

(4). Fine-turn the above Softmax model with Triplet loss.

CUDA_VISIBLE_DEVICES='0,1,2,3' python -u train_softmax.py --network m1 --loss-type 12 --lr 0.005 --mom 0.0 --per-batch-size 150 --data-dir ../datasets/faces_ms1m_112x112 --pretrained ../model-m1-softmax,50 --prefix ../model-m1-triplet

(5). Train LDPN107E network with Softmax loss on VGGFace2 dataset.

CUDA_VISIBLE_DEVICES='0,1,2,3,4,5,6,7' python -u train_softmax.py --network p107 --loss-type 0 --per-batch-size 64 --data-dir ../datasets/faces_vgg_112x112 --prefix ../model-p107-softmax

(6). Train MobileFaceNet network with ArcFace on MS1M dataset.

CUDA_VISIBLE_DEVICES='0,1,2,3' python -u train_softmax.py --network y1 --loss-type 4 --margin-s 128 --margin-m 0.5 --per-batch-size 128 --emb-size 128 --data-dir ../datasets/faces_ms1m_112x112 --wd 0.00004 --fc7-wd-mult 10.0 --prefix ../model-mobilefacenet-128
  1. Verification results.

LResNet100E-IR network trained on MS1M dataset with ArcFace loss:

Method LFW(%) CFP-FF(%) CFP-FP(%) AgeDB-30(%)
Ours 99.80+ 99.85+ 94.0+ 97.90+

LResNet50E-IR network trained on VGGFace2 dataset with ArcFace loss:

Method LFW(%) CFP-FF(%) CFP-FP(%) AgeDB-30(%)
Ours 99.7+ 99.6+ 97.1+ 95.7+

We report the verification accuracy after removing training set overlaps to strictly follow the evaluation metric. (C) means after cleaning

Dataset Identities Images Identites(C) Images(C) Acc Acc(C)
LFW 85742 3850179 80995 3586128 99.83 99.81
CFP-FP 85742 3850179 83706 3736338 94.04 94.03
AgeDB-30 85742 3850179 83775 3761329 98.08 97.87

Pretrained Models

You can use $INSIGHTFACE/src/eval/verification.py to test all the pre-trained models.

  1. LResNet50E-IR@BaiduDrive, @GoogleDrive Performance:
Method LFW(%) CFP-FF(%) CFP-FP(%) AgeDB-30(%) MegaFace(%)
Ours 99.80 99.83 92.74 97.76 97.64
  1. LResNet34E-IR@BaiduDrive Performance:
Method LFW(%) CFP-FF(%) CFP-FP(%) AgeDB-30(%) MegaFace(%)
Ours 99.65 99.77 92.12 97.70 96.70

Caffe LResNet50E-IR@BaiduDrive, converted by above MXNet model. Performance:

Method LFW(%) CFP-FF(%) CFP-FP(%) AgeDB-30(%) MegaFace1M(%)
Ours 99.74 -TBD- -TBD- -TBD- -TBD-

Verification Results on Combined Margin

A combined margin method was proposed as a function of target logits value and original θ:

COM(θ) = cos(m_1*θ+m_2) - m_3

For training with m1=0.9, m2=0.4, m3=0.15, run following command:

CUDA_VISIBLE_DEVICES='0,1,2,3' python -u train_softmax.py --network r100 --loss-type 5 --margin-a 0.9 --margin-m 0.4 --margin-b 0.15 --data-dir ../datasets/faces_ms1m_112x112  --prefix ../model-r100
Method m1 m2 m3 LFW CFP-FP AgeDB-30
W&F Norm Softmax 1 0 0 99.28 88.50 95.13
SphereFace 1.5 0 0 99.76 94.17 97.30
CosineFace 1 0 0.35 99.80 94.4 97.91
ArcFace 1 0.5 0 99.83 94.04 98.08
Combined Margin 1.2 0.4 0 99.80 94.08 98.05
Combined Margin 1.1 0 0.35 99.81 94.50 98.08
Combined Margin 1 0.3 0.2 99.83 94.51 98.13
Combined Margin 0.9 0.4 0.15 99.83 94.20 98.16

Test on MegaFace

In this part, we assume you are in the directory $INSIGHTFACE_ROOT/src/megaface/.

Note: We found there are overlap identities between facescrub dataset and Megaface distractors, which significantly affects the identification performance. This list is released under $INSIGHTFACE_ROOT/src/megaface/.

  1. Align all face images of facescrub dataset and megaface distractors. Please check the alignment scripts under $INSIGHTFACE_ROOT/src/align/.
  2. Generate feature files for both facescrub and megaface images.
python -u gen_megaface.py
  1. Remove Megaface noises which generates new feature files.
python -u remove_noises.py
  1. Run megaface development kit to produce final result.

512-D Feature Embedding

In this part, we assume you are in the directory $INSIGHTFACE_ROOT/deploy/. The input face image should be generally centre cropped. We use RNet+ONet of MTCNN to further align the image before sending it to the feature embedding network.

  1. Prepare a pre-trained model.
  2. Put the model under $INSIGHTFACE_ROOT/models/. For example, $INSIGHTFACE_ROOT/models/model-r34-amf.
  3. Run the test script $INSIGHTFACE_ROOT/deploy/test.py.

For single cropped face image(112x112), total inference time is only 17ms on our testing server(Intel E5-2660 @ 2.00GHz, Tesla M40, LResNet34E-IR).

Third-party Re-implementation

Face Alignment

Todo

Face Detection

Todo

Citation

If you find InsightFace useful in your research, please consider to cite the following related papers:

@article{deng2018arcface,
title={ArcFace: Additive Angular Margin Loss for Deep Face Recognition},
author={Deng, Jiankang and Guo, Jia and Zafeiriou, Stefanos},
journal={arXiv:1801.07698},
year={2018}
}

Contact

[Jia Guo](guojia[at]gmail.com)
[Jiankang Deng](jiankangdeng[at]gmail.com)

About

Face Recognition Project on MXNet

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages

  • Python 99.8%
  • Shell 0.2%