Assimilative Causal Inference
Abstract
Causal inference is fundamental across scientific disciplines, yet existing methods struggle to capture instantaneous, time-evolving causal relationships in complex, high-dimensional systems. In this paper, assimilative causal inference (ACI) is developed, which is a methodological framework that leverages Bayesian data assimilation to trace causes backward from observed effects. ACI solves the inverse problem rather than quantifying forward influence. It uniquely identifies dynamic causal interactions without requiring observations of candidate causes, accommodates short datasets, and, in principle, can be implemented in high-dimensional settings by employing efficient data assimilation algorithms. Crucially, it provides online tracking of causal roles that may reverse intermittently and facilitates a mathematically rigorous criterion for the causal influence range, revealing how far effects propagate. The effectiveness of ACI is demonstrated by complex dynamical systems showcasing intermittency and extreme events. ACI opens valuable pathways for studying complex systems, where transient causal structures are critical.
Cite
@article{arxiv.2505.14825,
title = {Assimilative Causal Inference},
author = {Marios Andreou and Nan Chen and Erik Bollt},
journal= {arXiv preprint arXiv:2505.14825},
year = {2026}
}
Comments
47 pages (Main Text pp. 1--17; Supplementary Information pp. 18--47), 11 figures (3 in Main Text, 8 in Supplementary Information). Published in Nature Communications. The MATLAB code used in the analyses and to generate the figures in this work can be found in https://github.com/marandmath/ACI_code . For further details visit https://mariosandreou.short.gy/ACI