This repository contains learning code that implements event representation learning as described in Gehrig et al. ICCV'19. The paper can be found here
If you use this code in an academic context, please cite the following work:
Daniel Gehrig, Antonio Loquercio, Konstantinos G. Derpanis, Davide Scaramuzza, "End-to-End Learning of Representations for Asynchronous Event-Based Data", The International Conference on Computer Vision (ICCV), 2019
@InProceedings{Gehrig_2019_ICCV,
author = {Daniel Gehrig and Antonio Loquercio and Konstantinos G. Derpanis and Davide Scaramuzza},
title = {End-to-End Learning of Representations for Asynchronous Event-Based Data},
booktitle = {Int. Conf. Comput. Vis. (ICCV)},
month = {October},
year = {2019}
}
- Python 3.7
- virtualenv
- cuda 10
Create a virtual environment with python3.7
and activate it
virtualenv venv -p /usr/local/bin/python3.7
source venv/bin/activate
Install all dependencies by calling
pip install -r requirements.txt
Before training, download the N-Caltech101
dataset and unzip it
wget http://rpg.ifi.uzh.ch/datasets/gehrig_et_al_iccv19/N-Caltech101.zip
unzip N-Caltech101.zip
Then start training by calling
python main.py --validation_dataset N-Caltech101/validation/ --training_dataset N-Caltech101/training/ --log_dir log/temp --device cuda:0
Here, validation_dataset
and training_dataset
should point to the folders where the training and validation set are stored.
log_dir
controls logging and device
controls on which device you want to train. Checkpoints and models with lowest validation loss will be saved in the root folder of log_dir
.
The N-Cars dataset can be downloaded here.
--num_worker
how many threads to use to load data--pin_memory
wether to pin memory or not--num_epochs
number of epochs to train--save_every_n_epochs
save a checkpoint every n epochs.--batch_size
batch size for training
Training can be visualized by calling tensorboard
tensorboard --logdir log/temp
Training and validation losses as well as classification accuracies are plotted. In addition, the learnt representations are visualized. The training and validation curves should look something like this:
Once trained, the models can be tested by calling the following script:
python testing.py --test N-Caltech101/testing/ --device cuda:0
Which will print the test score after iteration through the whole dataset.