This is a PyTorch implementation of DrQ from
Image Augmentation Is All You Need: Regularizing Deep Reinforcement Learning from Pixels by
Denis Yarats*, Ilya Kostrikov*, Rob Fergus.
*Equal contribution. Author ordering determined by coin flip.
If you use this repo in your research, please consider citing the paper as follows
@article{kostrikov2020image,
title={Image Augmentation Is All You Need: Regularizing Deep Reinforcement Learning from Pixels},
author={Ilya Kostrikov and Denis Yarats and Rob Fergus},
year={2020},
eprint={2004.13649},
archivePrefix={arXiv},
primaryClass={cs.LG}
}
We assume you have access to a gpu that can run CUDA 9.2. Then, the simplest way to install all required dependencies is to create an anaconda environment by running
conda env create -f conda_env.yml
After the instalation ends you can activate your environment with
source activate drq
To train the DrQ agent on the Cartpole Swingup
task run
python train.py env=cartpole_swingup
you can get the state-of-the-art performance in under 3 hours.
To reproduce the results from the paper run
python train.py env=cartpole_swingup batch_size=512 action_repeat=8
This will produce the runs
folder, where all the outputs are going to be stored including train/eval logs, tensorboard blobs, and evaluation episode videos. To launch tensorboard run
tensorboard --logdir runs
The console output is also available in a form:
| train | E: 5 | S: 5000 | R: 11.4359 | D: 66.8 s | BR: 0.0581 | ALOSS: -1.0640 | CLOSS: 0.0996 | TLOSS: -23.1683 | TVAL: 0.0945 | AENT: 3.8132
a training entry decodes as
train - training episode
E - total number of episodes
S - total number of environment steps
R - episode return
D - duration in seconds
BR - average reward of a sampled batch
ALOSS - average loss of the actor
CLOSS - average loss of the critic
TLOSS - average loss of the temperature parameter
TVAL - the value of temperature
AENT - the actor's entropy
while an evaluation entry
| eval | E: 20 | S: 20000 | R: 10.9356
contains
E - evaluation was performed after E episodes
S - evaluation was performed after S environment steps
R - average episode return computed over `num_eval_episodes` (usually 10)
DrQ demonstrates the state-of-the-art performance on a set of challenging image-based tasks from the DeepMind Control Suite (Tassa et al., 2018). We compare against PlaNet (Hafner et al., 2018), SAC-AE (Yarats et al., 2019), SLAC (Lee et al., 2019), CURL (Srinivas et al., 2020), and an upper-bound performance SAC States (Haarnoja et al., 2018). This follows the benchmark protocol established in PlaNet (Hafner et al., 2018).
DrQ demonstrates the state-of-the-art performance on an extended set of challenging image-based tasks from the DeepMind Control Suite (Tassa et al., 2018), following the benchmark protocol from Dreamer (Hafner et al., 2019). We compare against Dreamer (Hafner et al., 2019) and an upper-bound performance SAC States (Haarnoja et al., 2018).
We used kornia for data augmentation.