Inferring Network Evolutionary History via Structure-State Coupled Learning
Abstract
Inferring a network's evolutionary history from a single final snapshot with limited temporal annotations is fundamental yet challenging. Existing approaches predominantly rely on topology alone, which often provides insufficient and noisy cues. This paper leverages network steady-state dynamics -- converged node states under a given dynamical process -- as an additional and widely accessible observation for network evolution history inference. We propose CS, which explicitly models structure-state coupling to capture how topology modulates steady states and how the two signals jointly improve edge discrimination for formation-order recovery. Experiments on six real temporal networks, evaluated under multiple dynamical processes, show that CS consistently outperforms strong baselines, improving pairwise edge precedence accuracy by 4.0% on average and global ordering consistency (Spearman-) by 7.7% on average. CS also more faithfully recovers macroscopic evolution trajectories such as clustering formation, degree heterogeneity, and hub growth. Moreover, a steady-state-only variant remains competitive when reliable topology is limited, highlighting steady states as an independent signal for evolution inference.
Cite
@article{arxiv.2601.02121,
title = {Inferring Network Evolutionary History via Structure-State Coupled Learning},
author = {En Xu and Shihe Zhou and Huandong Wang and Jingtao Ding and Yong Li},
journal= {arXiv preprint arXiv:2601.02121},
year = {2026}
}