English

Learning Locally Interacting Discrete Dynamical Systems: Towards Data-Efficient and Scalable Prediction

Systems and Control 2024-05-29 v2 Machine Learning Systems and Control

Abstract

Locally interacting dynamical systems, such as epidemic spread, rumor propagation through crowd, and forest fire, exhibit complex global dynamics originated from local, relatively simple, and often stochastic interactions between dynamic elements. Their temporal evolution is often driven by transitions between a finite number of discrete states. Despite significant advancements in predictive modeling through deep learning, such interactions among many elements have rarely explored as a specific domain for predictive modeling. We present Attentive Recurrent Neural Cellular Automata (AR-NCA), to effectively discover unknown local state transition rules by associating the temporal information between neighboring cells in a permutation-invariant manner. AR-NCA exhibits the superior generalizability across various system configurations (i.e., spatial distribution of states), data efficiency and robustness in extremely data-limited scenarios even in the presence of stochastic interactions, and scalability through spatial dimension-independent prediction.

Keywords

Cite

@article{arxiv.2404.06460,
  title  = {Learning Locally Interacting Discrete Dynamical Systems: Towards Data-Efficient and Scalable Prediction},
  author = {Beomseok Kang and Harshit Kumar and Minah Lee and Biswadeep Chakraborty and Saibal Mukhopadhyay},
  journal= {arXiv preprint arXiv:2404.06460},
  year   = {2024}
}

Comments

Accepted in Learning for Dynamics and Control Conference (L4DC) 2024

R2 v1 2026-06-28T15:49:03.470Z