Non-Signaling Locality Lower Bounds for Dominating Set

Abstract

Minimum dominating set is a basic local covering problem and a core task in distributed computing. Despite extensive study, in the classic LOCAL model there exist significant gaps between known algorithms and lower bounds. Chang and Li prove an ( n)-locality lower bound for a constant factor approximation, while Kuhn--Moscibroda--Wattenhofer gave an algorithm beating this bound beyond -approximation, along with a weaker lower bound for this degree-dependent setting scaling roughly with \ / , n/ n\. Unfortunately, this latter bound is weak for small , and never recovers the Chang--Li bound, leaving central questions: does O( )-approximation require ( n) locality, and do such bounds extend beyond LOCAL? In this work, we take a major step toward answering these questions in the non-signaling model, which strictly subsumes the LOCAL, quantum-LOCAL, and bounded-dependence settings. We prove every O()-approximate non-signaling distribution for dominating set requires locality ( n/( · poly)). Further, we show for some β ∈ (0,1), every O(β )-approximate non-signaling distribution requires locality ( n/), which combined with the KMW bound yields a degree-independent ( n/ n) quantum-LOCAL lower bound for O(β)-approximation algorithms. The proof is based on two new low-soundness sensitivity lower bounds for label cover, one via Impagliazzo--Kabanets--Wigderson-style parallel repetition with degree reduction and one from a sensitivity-preserving reworking of the Dinur--Harsha framework, together with the reductions from label cover to set cover to dominating set and the sensitivity-to-locality transfer theorem of Fleming and Yoshida.