<p>We propose a bootstrap approximation method for the Hermitian one-matrix model that does not rely on positivity constraints. The theoretical foundation of this method is that the one-matrix model admits an eigenvalue distribution <i>ρ</i>(<i>λ</i>), and that the moments <i>w</i><sub><i>n</i></sub> generated from it satisfy the loop equations. Our framework is designed to numerically determine a self-consistent pair of <i>ρ</i>(<i>λ</i>) and <i>w</i><sub><i>n</i></sub> that simultaneously satisfies these two requirements. In the concrete implementation the least-squares method is employed, and since the sign problem is absent in this formulation, the method can be formally applied to the Minkowski one-matrix model as well, provided that the one-cut structure of the resolvent is assumed. Actual numerical calculations show that this bootstrap approximation reproduces, with very high accuracy, the exact solutions for Euclidean-type models and the perturbative results for Minkowski-type models.</p>

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Matrix bootstrap approximation without positivity constraint

  • Reishi Maeta

摘要

We propose a bootstrap approximation method for the Hermitian one-matrix model that does not rely on positivity constraints. The theoretical foundation of this method is that the one-matrix model admits an eigenvalue distribution ρ(λ), and that the moments wn generated from it satisfy the loop equations. Our framework is designed to numerically determine a self-consistent pair of ρ(λ) and wn that simultaneously satisfies these two requirements. In the concrete implementation the least-squares method is employed, and since the sign problem is absent in this formulation, the method can be formally applied to the Minkowski one-matrix model as well, provided that the one-cut structure of the resolvent is assumed. Actual numerical calculations show that this bootstrap approximation reproduces, with very high accuracy, the exact solutions for Euclidean-type models and the perturbative results for Minkowski-type models.