R. Orive scite author profile

The paper is devoted to a study of phase transitions in the Hermitian random matrix models with a polynomial potential. In an alternative equivalent language, we study families of equilibrium measures on the real line in a polynomial external field. The total mass of the measure is considered as the main parameter, which may be interpreted also either as temperature or time. Our main tools are differentiation formulas with respect to the parameters of the problem, and a representation of the equilibrium potential in terms of a hyperelliptic integral. Using this combination we introduce and investigate a dynamical system (system of ODEs) describing the evolution of families of equilibrium measures. On this basis we are able to systematically derive a number of new results on phase transitions, such as the local behavior of the system at all kinds of phase transitions, as well as to review a number of known ones.

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Riemann–Hilbert analysis for Jacobi polynomials orthogonal on a single contour

Martínez–Finkelshtein

Orive

2005

Journal of Approximation Theory

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Classical Jacobi polynomials P ( , ) n , with , > − 1, have a number of well-known properties, in particular the location of their zeros in the open interval (−1, 1). This property is no longer valid for other values of the parameters; in general, zeros are complex. In this paper we study the strong asymptotics of Jacobi polynomials where the real parameters n , n depend on n in such a way that lim n→∞ n n = A, lim n→∞ n n = B, with A, B ∈ R. We restrict our attention to the case where the limits A, B are not both positive and take values outside of the triangle bounded by the straight lines A = 0, B = 0 and A + B + 2 = 0.As a corollary, we show that in the limit the zeros distribute along certain curves that constitute trajectories of a quadratic differential. The non-hermitian orthogonality relations for Jacobi polynomials with varying parameters lie in the core of our approach; in the cases we consider, these relations hold on a single contour of the complex plane. The asymptotic analysis is performed using the Deift-Zhou steepest descent method based on the Riemann-Hilbert reformulation of Jacobi polynomials.

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On the convergence of certain Gauss-type quadrature formulas for unbounded intervals

et al. 1999

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Abstract. We consider the convergence of Gauss-type quadrature formulas for the integral ∞ 0 f (x)ω(x)dx, where ω is a weight function on the half line [0, ∞). The n-point Gauss-type quadrature formulas are constructed such that they are exact in the set of Laurent polynomialsIt is proved that under certain Carleman-type conditions for the weight and when p(n) or q(n) goes to ∞, then convergence holds for all functions f for which fω is integrable on [0, ∞). Some numerical experiments compare the convergence of these quadrature formulas with the convergence of the classical Gauss quadrature formulas for the half line.

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R. Orive

On asymptotic zero distribution of Laguerre and generalized Bessel polynomials with varying parameters

Zeros of Jacobi Polynomials With Varying Non-Classical Parameters

Phase Transitions and Equilibrium Measures in Random Matrix Models

Riemann–Hilbert analysis for Jacobi polynomials orthogonal on a single contour

On the convergence of certain Gauss-type quadrature formulas for unbounded intervals

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