Skip to content

Official implementation for "Identifying and Solving Conditional Image Leakage in Image-to-Video Diffusion Model" (NeurIPS 2024)

License

Notifications You must be signed in to change notification settings

thu-ml/cond-image-leakage

Folders and files

NameName
Last commit message
Last commit date

Latest commit

Β 

History

85 Commits
Β 
Β 
Β 
Β 
Β 
Β 
Β 
Β 

Repository files navigation

Identifying and Solving Conditional Image Leakage in Image-to-Video Diffusion Model

This is the official implementation for Identifying and Solving Conditional Image Leakage in Image-to-Video Diffusion Model (Accepted by NeurIPS 2024).

πŸ”† Overview

Diffusion models have obtained substantial progress in image-to-video (I2V) generation. However, such models are not fully understood. In this paper, we report a significant but previously overlooked issue in I2V diffusion models (I2V-DMs), namely, conditional image leakage. I2V-DMs tend to over-rely on the conditional image at large time steps, neglecting the crucial task of predicting the clean video from noisy inputs, which results in videos lacking dynamic and vivid motion. We further address this challenge from both inference and training aspects by presenting plug-and-play strategies accordingly. These strategies are validated on various I2V-DMs including DynamiCrafter, SVD and VideoCrafter1.

overview

βœ… To do list:

  • [2024.06.25]: Release code, models and project page.
  • [2024.08.11]: Add inference code for Animate-Anything and PIA

βš™οΈ Setup Environment

Our plug-and-play strategies can be applied to various I2V-DMs, allowing the direct use of their original environments. For example, to set up DynamiCrafter:

cd examples/DynamiCrafter
conda create -n dynamicrafter python=3.8.5
conda activate dynamicrafter
pip install -r requirements.txt

To set up VideoCrafter1:

cd examples/VideoCrafter
conda create -n videocrafter python=3.8.5
conda activate videocrafter
pip install -r requirements.txt

To set up SVD:

cd examples/SVD
conda create -n svd python=3.9.18
conda activate svd
pip install -r requirements.txt

To set up Animate-Anything:

cd examples/animate-anything
conda create -n animation python=3.10
conda activate animation
pip install -r requirements.txt

To set up PIA:

cd examples/PIA
conda env create -f pia.yml
conda activate pia

β˜€οΈ Dataset

Download the WebVid dataset from here, where we use Webvid-2M subset. Put .csv file in examples/dataset/results_2M_train.csv and video data in examples/dataset/. We use the raw data without any filters.

🧊 Inference Strategy

We clone the repo of DynamiCrafter and VideoCrafter1 and implement SVD by ourselves. We apply our plug and plug-and-play strategies on them.

πŸŽ’ Initial Noise Distribution

Model Resolution Initial Noise
DynamiCrafter 256x256 Initial Noise
DynamiCrafter 320x512 Initial Noise
DynamiCrafter 576x1024 Initial Noise
VideoCrafter 256x256 Initial Noise
VideoCrafter 320x512 Initial Noise
VideoCrafter 576x1024 Initial Noise
SVD 320 x 512 Initial Noise
SVD 576 x 1024 Initial Noise

πŸ˜„ Example Results

Model Conditional image Standard inference + Our inference strategy
DynamiCrafter320x512
VideoCrafter320x512
SVD 576x1024
Animate-Anything
PIA

DynamiCrafter

  1. Download the original DynamiCrafter checkpoints from the repository and put it in examples/DynamiCrafter/ckpt/original ,or download our DynamiCrafter-CIL from here and put it in examples/DynamiCrafter/ckpt/finetuned. Download the initial noise in the above table and put it in examples/DynamiCrafter/ckpt/.
  2. Run the following commands:
cd examples/DynamiCrafter

# for original DynamiCrafter with 320x512 resolution
sh inference_512.sh

# for our DynamiCrafter-CIL with 320x512 resolution
sh inference_CIL_512.sh

# for our DynamiCrafter-CIL with 576x1024 resolution
sh inference_CIL_1024.sh

The relevant parameters in inference.sh for our strategy are explained as follows:

  • M: the start timestep M.
  • whether_analytic_init: indicates whether to use Analytic-Init; 0 means it is not applied, while 1 means it is applied
  • analytic_init_path: the path for initializing the mean and variance of the noise if Analytic-Init is applied

Note that M=1000, whether_analytic_init=0 is the baseline.

The effect of start time M is as follows:

Conditional image M=1.00T M=0.94T M=0.90T M=0.86T M=0.82T
An appropriate M can enhance performance by increasing motion without compromising other performance. A too-small M delivers poor visual quality due to the training-inference gap.

SVD

  1. Download the pretrained SVD model and put it in examples/SVD/ckpt/pretrained/stable-video-diffusion-img2vid . Download our SVD-CIL from here and put it in examples/SVD/ckpt/finetuned. Download the initial noise in the above table and put them in examples/SVD/ckpt/.
  2. Run the following commands:
cd examples/SVD

# for original SVD
sh inference.sh

# for SVD-CIL with 320x512 resolution
sh inference_CIL_512.sh
 

The relevant parameters for inference are set in examples/SVD/config/inference.yaml,which are explained as follows:

  • sigma_max: the start time M.
  • analytic_init_path: the path for initializing the mean and variance of the noise if Analytic-Init is applied

VideoCrafter1

  1. Download the original VideoCrafter checkpoints from the repository and put it in examples/VideoCrafter/ckpt/original,or download our VideoCrafter-CIL from here and put it in examples/VideoCrafter/ckpt/finetuned.Download the initial noise in the above table and put them in examples/VideoCrafter/ckpt.
  2. Run the following commands:
cd examples/VideoCrafter

# for original VideoCrafter with 320x512 resolution
sh inference_512.sh

# for VideoCrafter-CIL with 320x512 resolution
sh inference_CIL_512.sh

The relevant parameters in inference.sh for our strategy are explained as follows:

  • M: the start time M
  • analytic_init_path: the path for initializing the mean and variance of the noise if Analytic-Init is applied

Animate-Anything

  1. Download the original Animate-Anything checkpoints from the repository and put it in cond-image-leakage/examples/animate-anything/output/latent/animate_anything_512_v1.02
  2. Run the following commands:
cd cond-image-leakage/examples/animate-anything
python inference.py --config example/config/concert.yaml

The relevant parameters in cond-image-leakage/examples/PIA/example/config/base.yaml for our strategy are explained as follows:

  • noise_scheduler_kwargs.num_train_timesteps: the start time M

PIA

  1. Download the original Animate-Anything checkpoints from the repository and put them following cond-image-leakage/examples/PIA/README.md.
  2. Run the following commands:
cd cond-image-leakage/examples/PIA

The relevant parameters in inference.sh for our strategy are explained as follows:

  • M: the start time M

πŸ”₯ Training Strategy

Similar to the inference strategy, we finetune the baselines based on the repository DynamiCrafter, VideoCrafter1 and SVD.

πŸ˜„ Example Results

Model Conditional image Finetuned-Baseline + Our training strategy
DynamiCrafter
VideoCrafter
SVD

DynamiCrafter

  1. Download the DynamiCrafter checkpoints from the repository and put them in examples/DynamiCrafter/ckpt/original.
  2. Run the following commands:
cd examples/DynamiCrafter
sh train.sh

The relevant parameters in train.sh for our strategy are explained as follows:

  • beta_m: the maximum noise level.
  • a: the exponent of center of the distribution: $\mu(t)=2t^a-1$, where $a > 0$.

The effect of beta_mis as follows:

Conditional Image beta_m=25 beta_m=100 beta_m=700
Higher beta_m correspond to more dynamic motion and lower temporal consistency and image alignment.

The effect of a is as follows:

Conditional Image a = 5.0 a = 1.0 a = 0.1

Lower a correspond to more dynamic motion and lower temporal consistency and image alignment.

SVD

  1. Download the SVD checkpoints from the repository and put them in examples/SVD/ckpt/pretrained/stable-video-diffusion-img2vid;
  2. Run the following commands:
cd examples/SVD
sh train.sh

The relevant parameters in examples/SVD/config/train.yamlfor our strategy are explained as follows:

  • beta_m: the maximum noise level. Higher beta_m correspond to more dynamic motion and lower temporal consistency and image alignment.
  • a: the exponent of center of the distribution: $\mu(t)=2t^a-1$, where $a > 0$. Lower $a$ correspond to more dynamic motion and lower temporal consistency and image alignment.

Note that original SVD first add noise on conditional image and then feed it into VAE. Here we first feed the conditional image into VAE and then add noise on the conditional latents.

VideoCrafter1

  1. Download the VideoCrafter checkpoints from the repository and put them in examples/VideoCrafter/original/ckpt/.
  2. Run the following commands:
cd examples/VideoCrafter
sh train.sh

The relevant parameters in train.sh for our strategy are explained as follows:

  • beta_m: the maximum noise level. Higher beta_m correspond to more dynamic motion and lower temporal consistency and image alignment.
  • a: the exponent of center of the distribution: $\mu(t)=2t^a-1$, where $a > 0$. Lower $a$ correspond to more dynamic motion and lower temporal consistency and image alignment.

πŸŽ’ Checkpoints

Naive fine-tuning and ours were trained under the same settings for fair comparison. In the future, we will release the model without watermark.

Model Naive Fine-Tuning Ours on Webvid Watermark-free
DynamiCrafter 320x512 320x512 320x512 576x1024
SVD 320x512 320x512 320x512
VideoCrafter1 320x512 320x512 -

πŸ˜„ Citation

If you find this repository helpful, please cite as:

@article{zhao2024identifying,
  title={Identifying and Solving Conditional Image Leakage in Image-to-Video Diffusion Model},
  author={Zhao, Min and Zhu, Hongzhou and Xiang, Chendong and Zheng, Kaiwen and Li, Chongxuan and Zhu, Jun},
  journal={arXiv preprint arXiv:2406.15735},
  year={2024}
}

❀️ Acknowledgements

This implementation is based on the following work:

About

Official implementation for "Identifying and Solving Conditional Image Leakage in Image-to-Video Diffusion Model" (NeurIPS 2024)

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published