DreamDiffusion is a framework for generating high-quality images from brain EEG signals. This document introduces the precesedures required for replicating the results in DreamDiffusion: Generating High-Quality Images from Brain EEG Signals
This paper introduces DreamDiffusion, a novel method for generating high-quality images directly from brain electroencephalogram (EEG) signals, without the need to translate thoughts into text. DreamDiffusion leverages pre-trained text-to-image models and employs temporal masked signal modeling to pre-train the EEG encoder for effective and robust EEG representations. Additionally, the method further leverages the CLIP image encoder to provide extra supervision to better align EEG, text, and image embeddings with limited EEG-image pairs. Overall, the proposed method overcomes the challenges of using EEG signals for image generation, such as noise, limited information, and individual differences, and achieves promising results. Quantitative and qualitative results demonstrate the effectiveness of the proposed method as a significant step towards portable and low-cost "thoughts-to-image", with potential applications in neuroscience and computer vision.
The datasets folder and pretrains folder are not included in this repository. Please download them from eeg and put them in the root directory of this repository as shown below. We also provide a copy of the Imagenet subset imagenet.
For Stable Diffusion, we just use standard SD1.5. You can download it from the official page of Stability. You want the file "v1-5-pruned.ckpt".
File path | Description
/pretrains
┣ 📂 models
┃ ┗ 📜 config.yaml
┃ ┗ 📜 v1-5-pruned.ckpt
┣ 📂 generation
┃ ┗ 📜 checkpoint_best.pth
┣ 📂 eeg_pretain
┃ ┗ 📜 checkpoint.pth (pre-trained EEG encoder)
/datasets
┣ 📂 imageNet_images (subset of Imagenet)
┗ 📜 block_splits_by_image_all.pth
┗ 📜 block_splits_by_image_single.pth
┗ 📜 eeg_5_95_std.pth
/code
┣ 📂 sc_mbm
┃ ┗ 📜 mae_for_eeg.py
┃ ┗ 📜 trainer.py
┃ ┗ 📜 utils.py
┣ 📂 dc_ldm
┃ ┗ 📜 ldm_for_eeg.py
┃ ┗ 📜 utils.py
┃ ┣ 📂 models
┃ ┃ ┗ (adopted from LDM)
┃ ┣ 📂 modules
┃ ┃ ┗ (adopted from LDM)
┗ 📜 stageA1_eeg_pretrain.py (main script for EEG pre-training)
┗ 📜 eeg_ldm.py (main script for fine-tuning stable diffusion)
┗ 📜 gen_eval_eeg.py (main script for generating images)
┗ 📜 dataset.py (functions for loading datasets)
┗ 📜 eval_metrics.py (functions for evaluation metrics)
┗ 📜 config.py (configurations for the main scripts)
Create and activate conda environment named dreamdiffusion from the env.yaml
conda env create -f env.yaml
conda activate dreamdiffusionWe also checkpoints to run the finetuing and decoding directly.
You can download the dataset for pretraining from here MOABB.
To perform the pre-training from scratch with defaults parameters, run
python3 code/stageA1_eeg_pretrain.pyHyper-parameters can be changed with command line arguments,
python3 code/stageA1_eeg_pretrain.py --mask_ratio 0.75 --num_epoch 800 --batch_size 2Or the parameters can also be changed in code/config.py
Multiple-GPU (DDP) training is supported, run with
python -m torch.distributed.launch --nproc_per_node=NUM_GPUS code/stageA1_eeg_pretrain.pyIn this stage, the cross-attention heads and pre-trained EEG encoder will be jointly optimized with EEG-image pairs.
python3 code/eeg_ldm.py --dataset EEG --num_epoch 300 --batch_size 4 --pretrain_mbm_path ../dreamdiffusion/pretrains/eeg_pretrain/checkpoint.pthRun this stage with our provided checkpoints: Here we provide a checkpoint ckpt, which you may want to try.
python3 code/gen_eval_eeg.py --dataset EEG --model_path pretrains/generation/checkpoint.pth
This code is built upon the publicly available code Mind-vis and StableDiffusion. Thanks these authors for making their excellent work and codes publicly available.
Please cite the following paper if you use this repository in your reseach.
@article{bai2023dreamdiffusion,
title={DreamDiffusion: Generating High-Quality Images from Brain EEG Signals},
author={Bai, Yunpeng and Wang, Xintao and Cao, Yanpei and Ge, Yixiao and Yuan, Chun and Shan, Ying},
journal={arXiv preprint arXiv:2306.16934},
year={2023}
}