No distributed quantum advantage for approximate graph coloring

July 18, 2023 Β· Declared Dead Β· πŸ› Symposium on the Theory of Computing

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Authors Xavier Coiteux-Roy, Francesco d'Amore, Rishikesh Gajjala, Fabian Kuhn, FranΓ§ois Le Gall, Henrik Lievonen, Augusto Modanese, Marc-Olivier Renou, Gustav Schmid, Jukka Suomela arXiv ID 2307.09444 Category cs.DC: Distributed Computing Cross-listed cs.CC, cs.DM, cs.ET, quant-ph Citations 21 Venue Symposium on the Theory of Computing Last Checked 4 months ago
Abstract
We give an almost complete characterization of the hardness of $c$-coloring $Ο‡$-chromatic graphs with distributed algorithms, for a wide range of models of distributed computing. In particular, we show that these problems do not admit any distributed quantum advantage. To do that: 1) We give a new distributed algorithm that finds a $c$-coloring in $Ο‡$-chromatic graphs in $\tilde{\mathcal{O}}(n^{\frac{1}Ξ±})$ rounds, with $Ξ±= \bigl\lfloor\frac{c-1}{Ο‡- 1}\bigr\rfloor$. 2) We prove that any distributed algorithm for this problem requires $Ξ©(n^{\frac{1}Ξ±})$ rounds. Our upper bound holds in the classical, deterministic LOCAL model, while the near-matching lower bound holds in the non-signaling model. This model, introduced by Arfaoui and Fraigniaud in 2014, captures all models of distributed graph algorithms that obey physical causality; this includes not only classical deterministic LOCAL and randomized LOCAL but also quantum-LOCAL, even with a pre-shared quantum state. We also show that similar arguments can be used to prove that, e.g., 3-coloring 2-dimensional grids or $c$-coloring trees remain hard problems even for the non-signaling model, and in particular do not admit any quantum advantage. Our lower-bound arguments are purely graph-theoretic at heart; no background on quantum information theory is needed to establish the proofs.
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