Polynomial control on weighted stability bounds and inversion norms of localized matrices on simple graphs

Abstract: The (un)weighted stability for some matrices is one of essential hypotheses in time-frequency analysis and applied harmonic analysis. In the first part of this paper, we show that for a localized matrix in a Beurling algebra, its weighted stabilities for different exponents and Muckenhoupt weights are equivalent to each other, and reciprocal of its optimal lower stability bound for one exponent and weight is controlled by a polynomial of reciprocal of its optimal lower stability bound for another exponent and weights. Inverse-closed Banach subalgebras of matrices with certain off-diagonal decay can be informally interpreted as localization preservation under inversion, which is of great importance in many mathematical and engineering fields. Let ${\mathcal B}(\ell^p_w)$ be the Banach algebra of bounded operators on the weighted sequence space $\ell^p_w$ on a simple graph. In the second part of this paper, we prove that Beurling algebras of localized matrices on a simple graph are inverse-closed in ${\mathcal B}(\ell^p_w)$ for all $1\le p<\infty$ and Muckenhoupt $A_p$-weights $w$, and the Beurling norm of the inversion of a matrix $A$ is bounded by a bivariate polynomial of the Beurling norm of the matrix $A$ and the operator norm of its inverse $A^{-1}$ in ${\mathcal B}(\ell^p_w)$.