Threshold Graphs Are Globally Synchronizing (2511.12646v1)

Abstract: Place n nodes on the unit circle and connect some pairs with springs that pull connected nodes toward each other. Which graphs always drive all nodes to converge to a single point, no matter where they start? This is known as the global synchronization problem of the Kuramoto model and is closely tied to the benign nonconvexity of its synchronization landscape. In this work, we show how this dynamical and continuous question can be reduced to a static and combinatorial one. We prove that threshold graphs, the graph class closed under adding isolated nodes and adding universal nodes, are globally synchronizing, based purely on a combinatorial analysis of unit-vector configurations in the plane. It is particularly striking that threshold graphs range from extremely sparse structures such as stars to the complete graph, suggesting that global synchronization in this class cannot be attributed to density. Our proof shows that global synchronization can instead emerge from a form of geometric symmetry.