A missing causal principle: Coordination
Abstract
We introduce the coordination principle, which states that perfect coordination, in the form of agreement on a uniformly random output, among N parties is possible only if they share a common cause. This principle is purely causal and can be viewed as a multipartite generalization of Reichenbach's common cause principle. We prove that quantum information theory satisfy the coordination principle in any network, and derive noise-tolerant Bell-like inequalities that certify the presence of a common cause. We further show that the principle is not a consequence of no-signaling and independence alone by constructing a concrete operational probabilistic theory that obeys both principles while still allowing perfect coordination without a common cause. This possibility arises only in fully general causal scenarios with intermediate transformations between preparations and measurements. We also formulate a genuinely quantum coordination task, showing that the preparation of a multipartite GHZ state requires a quantum common cause, which can be certified by Bell-like inequalities which are experimentally testable. Finally, we discuss the open problem of finding a quantitative, noise-tolerant version of the coordination principle that constrains approximate coordination in any reasonable causal theory. This work is the extended version of the more compact letter and provides all the technical details of the proofs.
Cite
@article{arxiv.2605.03132,
title = {A missing causal principle: Coordination},
author = {Daniel Centeno and Antoine Coquet and Maria Ciudad Alañón and Lucas Tendick and Marc-Olivier Renou and Elie Wolfe},
journal= {arXiv preprint arXiv:2605.03132},
year = {2026}
}
Comments
24 pages, 16 figures, comments are welcome