PyTorch implementation of Unsupervised Representation Learning by Predicting Image Rotations based on the official implementation.
The implementation supports the following datasets:
- CIFAR-10 / CIFAR-100
- SVHN
- Caltech101 / Caltech256
- STL10
- HAM10000
- ImageNet
Required python packages are listed in requirements.txt. All dependencies can be installed using pip
pip install -r requirements.txt
or using conda
conda install --file requirements.txt
RotNet training is started by running the following command (--pbar to show progress bar during training):
python main.py --pbar
All commandline arguments, which can be used to adapt the configuration of the RotNet training are defined and described in arguments.py.
By default the following configuration is run:
model: 'NIN_4'
dataset: 'cifar10'
lr: 0.1
wd: 0.0005
epochs: 100
batch_size: 128
device: 'cuda'
out_dir: 'rotation_prediction'
momentum: 0.9
In addition to these, the following arguments can be used to further configure the RotNet training process:
--device <cuda / cpu>: Specify whether training should be run on GPU (if available) or CPU--num-workers <num_workers>: Number of workers used by torch dataloader--resume <path to run_folder>: Resumes training of training run saved at specified path, e.g.'out/rotnet_training/run_0'. Dataset splits, model state, optimizer state, etc. are loaded and training is resumed with specified arguments.- see
arguments.pyfor more
Alternatively, the polyaxon.yaml-file can be used to start the RotNet training on a polyaxon-cluster:
polyaxon run -f polyaxon.yaml -u
For a general introduction to polyaxon and its commandline client, please refer to the official documentation
The training progress (loss, accuracy, etc.) can be monitored using tensorboard as follows:
tensorboard --logdir <result_folder>
This starts a tensorboard instance at localhost:6006, which can be opened in any common browser.
A trained RotNet model can be evaluated by running:
python3 eval.py --run-path out/rotnet_training/run_0 --pbar --device <cuda / cpu>
where --run-path specifies the path at which the run to be evaluated is saved. Alternatively, one can also check all
metrics over all epochs using the tensorboard file.
@inproceedings{
gidaris2018unsupervised,
title={Unsupervised Representation Learning by Predicting Image Rotations},
author={Spyros Gidaris and Praveer Singh and Nikos Komodakis},
booktitle={International Conference on Learning Representations},
year={2018},
url={https://openreview.net/forum?id=S1v4N2l0-},
}