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This research project implements a real-time object detection and pose estimation method as described in the paper, Tekin et al. "Real-Time Seamless Single Shot 6D Object Pose Prediction", CVPR 2018. (https://arxiv.org/abs/1711.08848).

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SINGLESHOTPOSE

This is the code for the following paper:

Bugra Tekin, Sudipta N. Sinha and Pascal Fua, "Real-Time Seamless Single Shot 6D Object Pose Prediction", CVPR 2018.

Introduction

We propose a single-shot approach for simultaneously detecting an object in an RGB image and predicting its 6D pose without requiring multiple stages or having to examine multiple hypotheses. The key component of our method is a new CNN architecture inspired by the YOLO network design that directly predicts the 2D image locations of the projected vertices of the object's 3D bounding box. The object's 6D pose is then estimated using a PnP algorithm. Paper, arXiv

SingleShotPose

Citation

If you use this code, please cite the following

@inproceedings{tekin18,
      TITLE = {{Real-Time Seamless Single Shot 6D Object Pose Prediction}},
      AUTHOR = {Tekin, Bugra and Sinha, Sudipta N. and Fua, Pascal},
      BOOKTITLE = {CVPR},
      YEAR = {2018}
}

License

SingleShotPose is released under the MIT License (refer to the LICENSE file for details).

Environment and dependencies

The code is tested on Linux with CUDA v9 and cudNN v7. The implementation is based on PyTorch 1.1.0 and tested on Python3.5. The code requires the following dependencies that could be installed with conda or pip: numpy, scipy, PIL, opencv-python

apt install pip3
export LC_ALL=C
pip3 install torch=1.1.0 torchvision scipy pillow opencv-python

Downloading and preparing the data

Inside the main code directory, run the following to download and extract (1) the preprocessed LINEMOD dataset, (2) trained models for the LINEMOD dataset, (3) the trained model for the OCCLUSION dataset, (4) background images from the VOC2012 dataset respectively.

wget -O LINEMOD.tar --no-check-certificate "https://onedrive.live.com/download?cid=05750EBEE1537631&resid=5750EBEE1537631%21135&authkey=AJRHFmZbcjXxTmI"
wget -O backup.tar --no-check-certificate "https://onedrive.live.com/download?cid=0C78B7DE6C569D7B&resid=C78B7DE6C569D7B%21191&authkey=AP183o4PlczZR78"
wget -O multi_obj_pose_estimation/backup_multi.tar --no-check-certificate  "https://onedrive.live.com/download?cid=05750EBEE1537631&resid=5750EBEE1537631%21136&authkey=AFQv01OSbvhGnoM"
wget https://pjreddie.com/media/files/VOCtrainval_11-May-2012.tar
wget https://pjreddie.com/media/files/darknet19_448.conv.23 -P cfg/
tar xf LINEMOD.tar
tar xf backup.tar
tar xf multi_obj_pose_estimation/backup_multi.tar -C multi_obj_pose_estimation/
tar xf VOCtrainval_11-May-2012.tar

Alternatively, you can directly go to the links above and manually download and extract the files at the corresponding directories. The whole download process might take a long while (~60 minutes).

Training the model

To train the model run,

python3 train.py datafile cfgfile initweightfile

e.g.

python3 train.py cfg/ape.data cfg/yolo-pose.cfg backup/ape/init.weights

[datafile] contains information about the training/test splits and 3D object models

[cfgfile] contains information about the network structure

[initweightfile] contains initialization weights. The weights "backup/[OBJECT_NAME]/init.weights" are pretrained on LINEMOD for faster convergence. We found it effective to pretrain the model without confidence estimation first and fine-tune the network later on with confidence estimation as well. "init.weights" contain the weights of these pretrained networks. However, you can also still train the network from a more crude initialization (with weights trained on ImageNet). This usually results in a slower and sometimes slightly worse convergence. You can find in cfg/ folder the file <<darknet19_448.conv.23>> that includes the network weights pretrained on ImageNet. Alternatively, you can pretrain your own weights by setting the regularization parameter for the confidence loss to 0 as explained in "Pretraining the model" section.

At the start of the training you will see an output like this:

layer     filters    size              input                output
    0 conv     32  3 x 3 / 1   416 x 416 x   3   ->   416 x 416 x  32
    1 max          2 x 2 / 2   416 x 416 x  32   ->   208 x 208 x  32
    2 conv     64  3 x 3 / 1   208 x 208 x  32   ->   208 x 208 x  64
    3 max          2 x 2 / 2   208 x 208 x  64   ->   104 x 104 x  64
    ...
   30 conv     20  1 x 1 / 1    13 x  13 x1024   ->    13 x  13 x  20
   31 detection

This defines the network structure. During training, the best network model is saved into the "model.weights" file. To train networks for other objects, just change the object name while calling the train function, e.g., "python3 train.py cfg/duck.data cfg/yolo-pose.cfg backup/duck/init.weights"

Testing the model

To test the model run

python3 valid.py datafile cfgfile weightfile
e.g.,
python3 valid.py cfg/ape.data cfg/yolo-pose.cfg backup/ape/model_backup.weights

[weightfile] contains our trained models.

Pretraining the model (Optional)

Models are already pretrained but if you would like to pretrain the network from scratch and get the initialization weights yourself, you can run the following:

python3 train.py cfg/ape.data cfg/yolo-pose-pre.cfg cfg/darknet19_448.conv.23
cp backup/ape/model.weights backup/ape/init.weights

During pretraining the regularization parameter for the confidence term is set to "0" in the config file "cfg/yolo-pose-pre.cfg". "darknet19_448.conv.23" includes the weights of YOLOv2 trained on ImageNet.

Multi-object pose estimation on the OCCLUSION dataset

Inside multi_obj_pose_estimation/ folder

Testing:

python3 valid_multi.py cfgfile weightfile
e.g.,
python3 valid_multi.py cfg/yolo-pose-multi.cfg backup_multi/model_backup.weights

Training:

python3 train_multi.py datafile cfgfile weightfile

e.g.,

python3 train_multi.py cfg/occlusion.data cfg/yolo-pose-multi.cfg backup_multi/init.weights

Label files

Our label files consist of 21 values. We predict 9 points corresponding to the centroid and corners of the 3D object model. Additionally we predict the class in each cell. That makes 9x2+1 = 19 points. In multi-object training, during training, we assign whichever anchor box has the most similar size to the current object as the responsible one to predict the 2D coordinates for that object. To encode the size of the objects, we have additional 2 numbers for the range in x dimension and y dimension. Therefore, we have 9x2+1+2 = 21 numbers.

Respectively, 21 numbers correspond to the following: 1st number: class label, 2nd number: x0 (x-coordinate of the centroid), 3rd number: y0 (y-coordinate of the centroid), 4th number: x1 (x-coordinate of the first corner), 5th number: y1 (y-coordinate of the first corner), ..., 18th number: x8 (x-coordinate of the eighth corner), 19th number: y8 (y-coordinate of the eighth corner), 20th number: x range, 21st number: y range.

The coordinates are normalized by the image width and height: x / image_width and y / image_height. This is useful to have similar output ranges for the coordinate regression and object classification tasks.

Training on your own dataset

To train on your own dataset, simply create the same folder structure with the provided LINEMOD dataset and adjust the paths in cfg/[OBJECT].data, [DATASET]/[OBJECT]/train.txt and [DATASET]/[OBJECT]/test.txt files. The folder for each object should contain the following:

(1) a folder containing image files,
(2) a folder containing label files (labels should be created using the same output representation explained above),
(3) a text file containing the training images (train.txt),
(4) a text file contraining the test images (test.txt),
(5) a .ply file containing the 3D object model
(6) optionally, a folder containing segmentation masks (if you want to change the background of your training images to be more robust to diverse backgrounds),

Acknowledgments

The code is written by Bugra Tekin and is built on the YOLOv2 implementation of the github user @marvis

Contact

For any questions or bug reports, please contact Bugra Tekin

About

This research project implements a real-time object detection and pose estimation method as described in the paper, Tekin et al. "Real-Time Seamless Single Shot 6D Object Pose Prediction", CVPR 2018. (https://arxiv.org/abs/1711.08848).

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