A degree 4 sum-of-squares lower bound for the clique number of the Paley graph
November 04, 2022 Β· Declared Dead Β· π Cybersecurity and Cyberforensics Conference
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Authors
Dmitriy Kunisky, Xifan Yu
arXiv ID
2211.02713
Category
cs.DS: Data Structures & Algorithms
Cross-listed
cs.CC,
math.NT,
math.OC
Citations
3
Venue
Cybersecurity and Cyberforensics Conference
Last Checked
4 months ago
Abstract
We prove that the degree 4 sum-of-squares (SOS) relaxation of the clique number of the Paley graph on a prime number $p$ of vertices has value at least $Ξ©(p^{1/3})$. This is in contrast to the widely believed conjecture that the actual clique number of the Paley graph is $O(\mathrm{polylog}(p))$. Our result may be viewed as a derandomization of that of Deshpande and Montanari (2015), who showed the same lower bound (up to $\mathrm{polylog}(p)$ terms) with high probability for the ErdΕs-RΓ©nyi random graph on $p$ vertices, whose clique number is with high probability $O(\log(p))$. We also show that our lower bound is optimal for the Feige-Krauthgamer construction of pseudomoments, derandomizing an argument of Kelner. Finally, we present numerical experiments indicating that the value of the degree 4 SOS relaxation of the Paley graph may scale as $O(p^{1/2 - Ξ΅})$ for some $Ξ΅> 0$, and give a matrix norm calculation indicating that the pseudocalibration proof strategy for SOS lower bounds for random graphs will not immediately transfer to the Paley graph. Taken together, our results suggest that degree 4 SOS may break the "$\sqrt{p}$ barrier" for upper bounds on the clique number of Paley graphs, but prove that it can at best improve the exponent from $1/2$ to $1/3$.
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