Skip to content

jeongwhanchoi/BSPM

Folders and files

NameName
Last commit message
Last commit date

Latest commit

 

History

16 Commits
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Repository files navigation

Blurring-Sharpening Process Models for Collaborative Filtering

GitHub Repo stars Twitter Follow arXiv Hits

PWC PWC PWC PWC PWC PWC

Introduction

Score-based generative models (SGMs) Our blurring-sharpening process models (BSPMs)

The comparison between SGMs and our proposed BSPMs. SGMs, a recently proposed paradigm for deep generative tasks, outperform generative adversarial networks (GANs), variational autoencoders (VAEs), and many other generative models.

  • SGMs use two stochastic processes, one for the forward perturbation and the other for the backward recovery. Since the recovery process is stochastic, it does not typically converge to the original sample $\mathbf{x}(0)$ but to another similar sample. After training, only the recovery process is used to generate fake samples from random noisy vectors $\mathbf{x}(T) \sim \mathcal{N}(\mathbf{\mu}, \mathbf{\sigma})$.
  • Our BSPMs use two deterministic blurring and sharpening processes. Unlike SGMs trained with many images, our BSPMs process only one interaction matrix; therefore, we use deterministic processes.

Citation

Please cite our paper if using this code.

@inproceedings{choi2023bspm,
  title={Blurring-Sharpening Process Models for Collaborative Filtering},
  author={Choi, Jeongwhan and Hong, Seoyoung and Park, Noseong and Cho, Sung-Bae},
  booktitle={Proceedings of the ACM Conference on Research and Development in Information Retrieval (SIGIR)},
  year={2023}
}

Requirement:

conda env create -f environment.yml
conda activate bspm

Run experiment:

go to folder bspm

  • Gowalla
# CPU
python main.py --dataset="gowalla" --topks="[20]" --simple_model="bspm" --solver_shr="rk4" --K_s=1 --T_s=2.5 --final_sharpening=True --idl_beta=0.2 --factor_dim=448

# GPU
python main.py --dataset="gowalla" --topks="[20]" --simple_model="bspm-torch" --testbatch=2048 --solver_shr="rk4" --K_s=1 --T_s=2.5 --final_sharpening=True --idl_beta=0.2 --factor_dim=448 
  • Yelp2018
# CPU
python main.py --dataset="yelp2018" --topks="[20]" --simple_model="bspm" --solver_shr="euler" --K_s=1 --T_s=1.2 --final_sharpening=True --t_point_combination=True --factor_dim=384

# GPU
python main.py --dataset="yelp2018" --topks="[20]" --simple_model="bspm-torch" --testbatch=2048 --solver_shr="euler" --K_s=1 --T_s=1.2 --final_sharpening=True --t_point_combination=True  --factor_dim=384
  • Amazon-book
# CPU
python main.py --dataset="amazon-book" --topks="[20]" --simple_model="bspm" --solver_shr="rk4" --K_s=2 --T_s=2.2 --final_sharpening=False
# GPU
python main.py --dataset="amazon-book" --topks="[20]" --simple_model="bspm-torch" --testbatch=2048 --solver_shr="rk4" --K_s=2 --T_s=2.2 --final_sharpening=False 

Arguements

  • final_sharpening
    • True: EM (Early Merge)
    • False: LM (Late Merge)
  • solver_shr
    • euler: Euler method
    • rk4: Runge-Kutta 4th order method
  • K_s:
    • The number of sharpening step
  • T_s:
    • The terminal time of sharpening ODE
  • t_point_combination:
    • True: Use the combination of t points
  • idl_beta:
    • The beta value of IDL
  • factor_dim:
    • The dimension of latent factors

Star History

Star History Chart

About

Blurring-Sharpening Process Models for Collaborative Filtering, SIGIR'23

Topics

Resources

License

Stars

Watchers

Forks

Releases

No releases published

Packages

No packages published

Languages