Recent research in tabular data synthesis has focused on single tables, whereas real-world applications often involve complex data with tens or hundreds of interconnected tables. Previous approaches to synthesizing multi-relational (multitable)2 data fall short in two key aspects: scalability for larger datasets and capturing long-range dependencies, such as correlations between attributes spread across different tables. Inspired by the success of diffusion models in tabular data modeling, we introduce Cluster Latent Variable guided Denoising Diffusion Probabilistic Models (ClavaDDPM). This novel approach leverages clustering labels as intermediaries to model relationships between tables, specifically focusing on foreign key constraints. ClavaDDPM leverages the robust generation capabilities of diffusion models while incorporating efficient algorithms to propagate the learned latent variables across tables. This enables ClavaDDPM to capture longrange dependencies effectively. Extensive evaluations on multi-table datasets of varying sizes show that ClavaDDPM significantly outperforms existing methods for these long-range dependencies while remaining competitive on utility metrics for single-table data.

Bibtex

@misc{pang2024clavaddpmmultirelationaldatasynthesis,
title={ClavaDDPM: Multi-relational Data Synthesis with Cluster-guided Diffusion Models},
author={Wei Pang and Masoumeh Shafieinejad and Lucy Liu and Stephanie Hazlewood and Xi He},
year={2024},
eprint={2405.17724},
archivePrefix={arXiv},
primaryClass={cs.AI},
url={https://arxiv.org/abs/2405.17724},
}

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