English

Partially Functional Dynamic Backdoor Diffusion-based Causal Model

Machine Learning 2026-04-07 v3 Machine Learning Statistics Theory Statistics Theory

Abstract

Causal inference in spatio-temporal settings is critically hindered by unmeasured confounders with complex spatio-temporal dynamics and the prevalence of multi-resolution data. While diffusion models present a promising avenue for estimating structural causal models, existing approaches are limited by assumptions of causal sufficiency or static confounding, failing to capture the region-specific, temporally dependent nature of real-world latent variables or to directly handle functional variables. We bridge this gap by introducing the Partially Functional Dynamic Backdoor Diffusion-based Causal Model (PFD-BDCM), a unified generative framework designed to simultaneously tackle causal inference with dynamic confounding and functional data. Our approach formalizes a novel structural causal model that captures spatio-temporal dependencies in latent confounders through conditional autoregressive processes, represents functional variables via basis expansion coefficients treated as standard graph nodes, and integrates valid backdoor adjustment into a diffusion-based generative process. We provide theoretical guarantees on the preservation of causal effects under basis expansion and derive error bounds for counterfactual estimates. Experiments on synthetic data and a real-world air pollution case study demonstrate that PFD-BDCM outperforms existing methods across observational, interventional, and counterfactual queries. This work provides a rigorous and practical tool for robust causal inference in complex spatio-temporal systems characterized by non-stationarity and multi-resolution data.

Keywords

Cite

@article{arxiv.2509.00472,
  title  = {Partially Functional Dynamic Backdoor Diffusion-based Causal Model},
  author = {Xinwen Liu and Lei Qian and Song Xi Chen and Niansheng Tang},
  journal= {arXiv preprint arXiv:2509.00472},
  year   = {2026}
}

Comments

16 pages, 2 figures

R2 v1 2026-07-01T05:13:27.948Z