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The official PyTorch implementation of img2pose: Face Alignment and Detection via 6DoF, Face Pose Estimation

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img2pose: Face Alignment and Detection via 6DoF, Face Pose Estimation

License: CC BY-NC 4.0 PWC PWC

Figure 1: We estimate the 6DoF rigid transformation of a 3D face (rendered in silver), aligning it with even the tiniest faces, without face detection or facial landmark localization. Our estimated 3D face locations are rendered by descending distances from the camera, for coherent visualization.


This repository provides a novel method for six degrees of fredoom (6DoF) detection on multiple faces without the need of prior face detection. After prediction, one can visualize the detections (as show in the figure above), customize projected bounding boxes, or crop and align each face for further processing. See details below.

Table of contents

Paper details

Vítor Albiero, Xingyu Chen, Xi Yin, Guan Pang, Tal Hassner, "img2pose: Face Alignment and Detection via 6DoF, Face Pose Estimation," arXiv:2012.07791, Dec., 2020


We propose real-time, six degrees of freedom (6DoF), 3D face pose estimation without face detection or landmark localization. We observe that estimating the 6DoF rigid transformation of a face is a simpler problem than facial landmark detection, often used for 3D face alignment. In addition, 6DoF offers more information than face bounding box labels. We leverage these observations to make multiple contributions: (a) We describe an easily trained, efficient, Faster R-CNN--based model which regresses 6DoF pose for all faces in the photo, without preliminary face detection. (b) We explain how pose is converted and kept consistent between the input photo and arbitrary crops created while training and evaluating our model. (c) Finally, we show how face poses can replace detection bounding box training labels. Tests on AFLW2000-3D and BIWI show that our method runs at real-time and outperforms state of the art (SotA) face pose estimators. Remarkably, our method also surpasses SotA models of comparable complexity on the WIDER FACE detection benchmark, despite not been optimized on bounding box labels.


If you use any part of our code or data, please cite our paper.

  title={img2pose: Face Alignment and Detection via 6DoF, Face Pose Estimation},
  author={Albiero, Vítor and Chen, Xingyu and Yin, Xi and Pang, Guan and Hassner, Tal},
  journal={arXiv preprint arXiv:2012.07791},


Install dependecies with Python 3.

pip install -r requirements.txt
Install the renderer, which is used to visualize predictions. The renderer implementation is forked from here.
cd Sim3DR


Prepare WIDER FACE dataset

First, download our annotations as instructed in Annotations.

Download WIDER FACE dataset and extract to datasets/WIDER_Face.

Then, to create the train and validation files (LMDB), run the following scripts.

--json_list ./annotations/WIDER_train_annotations.txt
--dataset_path ./datasets/WIDER_Face/WIDER_train/images/
--dest ./datasets/lmdb/

This first script will generate a LMDB dataset, which contains the training images along with annotations. It will also output a pose mean and std deviation files, which will be used for training and testing.

--json_list ./annotations/WIDER_val_annotations.txt 
--dataset_path ./datasets/WIDER_Face/WIDER_val/images/ 
--dest ./datasets/lmdb
This second script will create a LMDB containing the validation images along with annotations.


Once the LMDB train/val files are created, to start training simple run the script below.

--pose_mean ./datasets/lmdb/WIDER_train_annotations_pose_mean.npy
--pose_stddev ./datasets/lmdb/WIDER_train_annotations_pose_stddev.npy
--workspace ./workspace/
--train_source ./datasets/lmdb/WIDER_train_annotations.lmdb
--val_source ./datasets/lmdb/WIDER_val_annotations.lmdb
--prefix trial_1
--batch_size 2
--max_size 1400
For now, only single GPU training is tested. Distributed training is partially implemented, PRs welcome.

Training on your own dataset

If your dataset has facial landmarks and bounding boxes already annotated, store them into JSON files following the same format as in the WIDER FACE annotations.

If not, run the script below to annotate your dataset. You will need a detector and import it inside the script.

python3 utils/ 
--image_list list_of_images.txt 
--output_path ./annotations/dataset_name
After the dataset is annotated, create a list pointing to the JSON files there were saved. Then, follow the steps in Prepare WIDER FACE dataset replacing the WIDER annotations with your own dataset annotations. Once the LMDB and pose files are created, follow the steps in Train replacing the WIDER LMDB and pose files with your dataset own files.


To evaluate with the pretrained model, download the model from Model Zoo, and extract it to the main folder. It will create a folder called models, which contains the model weights and the pose mean and std dev that was used for training.

If evaluating with own trained model, change the pose mean and standard deviation to the ones trained with.

Visualizing trained model

To visualize a trained model on the WIDER FACE validation set run the notebook visualizetrainedmodel_predictions.

WIDER FACE dataset evaluation

If you haven't done already, download the WIDER FACE dataset and extract to datasets/WIDER_Face.

python3 evaluation/ 
--dataset_path datasets/WIDER_Face/WIDER_val/images/
--dataset_list datasets/WIDER_Face/wider_face_split/wider_face_val_bbx_gt.txt
--pretrained_path models/img2pose_v1.pth
--output_path results/WIDER_FACE/Val/

To check mAP and plot curves, download the eval tools and point to results/WIDER_FACE/Val.

AFLW2000-3D dataset evaluation

Download the AFLW2000-3D dataset and unzip to datasets/AFLW2000.

Run the notebook aflw20003d_evaluation.

BIWI dataset evaluation

Download the BIWI dataset and unzip to datasets/BIWI.

Run the notebook biwi_evaluation.

Testing on your own images

Run the notebook testownimages.

Output customization

For every face detected, the model outputs by default: - Pose: pitch, yaw, roll, horizontal translation, vertical translation, and scale - Projected bounding boxes: left, top, right, bottom - Face scores: 0 to 1

Since the projected bounding box without expansion ends at the start of the forehead, we provide a way of expanding the forehead invidually, along with default x and y expansion.

To customize the size of the projected bounding boxes, when creating the model change any of the bounding box expansion variables as shown below (a complete example can be seen at visualizetrainedmodel_predictions). ```

how much to expand in width

bboxxfactor = 1.1

how much to expand in height

bboxyfactor = 1.1

how much to expand in the forehead

expand_forehead = 0.3

img2posemodel = img2poseModel( ...,
xfactor=bboxxfactor, bboxyfactor=bboxyfactor, expandforehead=expand_forehead, ) ```

Align faces

To align the detected faces, call the function bellow passing the reference points, the image with the faces to align, and the poses outputted by img2pose. The function will return a list with PIL images containing one aligned face per give pose. ``` from utils.poseoperations import alignfaces

load reference points

threedpoints = np.load("posereferences/reference3d5pointstrans.npy")

alignedfaces = alignfaces(threed_points, img, poses) ```


Model Zoo


Data Zoo


Check license for license details.

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