Combinatorial Complex Score-based Diffusion Modelling through Stochastic Differential Equations

arXiv - MATH - Algebraic Topology Pub Date : 2024-06-07 DOI:arxiv-2406.04916

Adrien Carrel

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Abstract

Graph structures offer a versatile framework for representing diverse patterns in nature and complex systems, applicable across domains like molecular chemistry, social networks, and transportation systems. While diffusion models have excelled in generating various objects, generating graphs remains challenging. This thesis explores the potential of score-based generative models in generating such objects through a modelization as combinatorial complexes, which are powerful topological structures that encompass higher-order relationships. In this thesis, we propose a unified framework by employing stochastic differential equations. We not only generalize the generation of complex objects such as graphs and hypergraphs, but we also unify existing generative modelling approaches such as Score Matching with Langevin dynamics and Denoising Diffusion Probabilistic Models. This innovation overcomes limitations in existing frameworks that focus solely on graph generation, opening up new possibilities in generative AI. The experiment results showed that our framework could generate these complex objects, and could also compete against state-of-the-art approaches for mere graph and molecule generation tasks.

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通过随机微分方程建立基于复杂分数的组合扩散模型

图结构为表示自然界和复杂系统中的各种模式提供了一个通用框架，适用于分子化学、社交网络和运输系统等领域。虽然扩散模型在生成各种对象方面表现出色，但生成图仍然具有挑战性。本论文通过对组合复合物的建模，探索基于分数的生成模型在生成此类对象方面的潜力，组合复合物是包含高阶关系的强大拓扑结构。在本论文中，我们采用随机微分方程提出了一个统一的框架。我们不仅推广了图和超图等复杂对象的生成，而且还统一了现有的生成建模方法，如分数匹配与朗格文动力学和失真扩散概率模型。这一创新克服了现有框架只关注图生成的局限性，为生成式人工智能开辟了新的可能性。实验结果表明，我们的框架可以生成这些复杂的对象，还可以在图和分子生成任务方面与最先进的方法竞争。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - MATH - Algebraic Topology

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