Spectral upper bound on the quantum $k$-independence number of a graph

Abstract: A well known upper bound for the independence number $\alpha(G)$ of a graph $G$, due to Cvetkovi ́c, is that \begin{equation*}\alpha(G) \le n^0 + \min\{n^+ , n^-\}\end{equation*}where $(n^+, n^0, n^-)$ is the inertia of $G$. We prove that this bound is also an upper bound for the quantum independence number $\alpha_q$(G), where $\alpha_q(G) \ge \alpha(G)$ and for some graphs $\alpha_q(G) \gg \alpha(G)$. We identify numerous graphs for which $\alpha(G) = \alpha_q(G)$, thus increasing the number of graphs for wh… Show more

The inertia bound is far from tight

The inertia bound is far from tight

Optimization of eigenvalue bounds for the independence and chromatic number of graph powers