Asymptotic zero distribution of random orthogonal polynomials

Bloom, Thomas; Dauvergne, Duncan

doi:10.1214/19-aop1337

Cited by 12 publications

(12 citation statements)

References 26 publications

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“…It was shown by Wilkins [25], after some intermediate results cited in [25], that there exist constants A p , p ≥ 0, such that E n (R) has an asymptotic expansion of the form Many subsequent results on random polynomials are concerned with relaxing the conditions on random coefficients, see, for example, [13,18,10], or the behavior of the counting measures of zeros of random polynomials as in [21,6,14,5,19,2,20,17,4,9]. Our primary interest lies in studying the expected number of real zeros when the basis is a family of orthogonal polynomials in the spirit of [7,8,26,16].…”

Section: Introduction and Main Resultsmentioning

confidence: 99%

An asymptotic expansion for the expected number of real zeros of real random polynomials spanned by OPUC

Aljubran

Yattselev

2019

Journal of Mathematical Analysis and Applications

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Let {ϕ i } ∞ i=0 be a sequence of orthonormal polynomials on the unit circle with respect to a positive Borel measure µ that is symmetric with respect to conjugation. We study asymptotic behavior of the expected number of real zeros, say E n (µ), of random polynomials P n (z) := n i=0 Key words: random polynomials, orthogonal polynomials on the unit circle, expected number of real zeros, asymptotic expansion

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Section: Introduction and Main Resultsmentioning

confidence: 99%

An asymptotic expansion for the expected number of real zeros of real random polynomials spanned by OPUC

Aljubran

Yattselev

2019

Journal of Mathematical Analysis and Applications

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“…As discussed above, the sufficiency of condition (6) for Theorem 1.2 was proven as Theorem 5.3 in [6] for Bernstein-Markov measures τ with regular support K. These proofs can be extended to include all cases of Theorem 1.2 with a few modifications. The proof ideas can also be used to show the convergence in probability in Theorem 1.4 when the sequence {p n } has an additional assumption about root concentration or speed of convergence (i.e.…”

Section: Introductionmentioning

confidence: 93%

“…Bloom and Dauvergne [6] extended this result by showing that µ Gn converges to µ K in probability for any sequence of polynomials {p j } generated from a measure τ satisfying the Bernstein-Markov property (we will discuss this property later in the introduction) under the condition (3) P( ξ 0 > e n ) = o(n −1 ).…”

Section: Introductionmentioning

confidence: 93%

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A necessary and sufficient condition for convergence of the zeros of random polynomials

Dauvergne

2019

Preprint

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Consider random polynomials of the form Gn = ∑ n i=0 ξipi, where the ξi are i.i.d. non-degenerate complex random variables, and {pi} is a sequence of orthonormal polynomials with respect to a regular measure τ supported on a compact set K. We show that the zero measure of Gn converges weakly almost surely to the equilibrium measure of K if and only if E log(1 + ξ0 ) < ∞. This generalizes the corresponding result of Ibragimov and Zaporozhets in the case when pi(z) = z i . We also show that the zero measure of Gn converges weakly in probability to the equilibrium measure of K if and only if P( ξ0 > e n ) = o(n −1 ).Our proofs rely on results from small ball probability and exploit the structure of general orthogonal polynomials. Our methods also work for sequences of asymptotically minimal polynomials in L p (τ ), where p ∈ (0, ∞]. In particular, sequences of L p -minimal polynomials and (normalized) Faber and Fekete polynomials fall into this class.

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“…Random polynomials with non-Gaussian coefficients were also considered by various authors (see eg. [DS,BL,Bay1,Bay3,BD] among others). In [Bay4] for radially symmetric weight functions, we provided a necessary and sufficient condition on random coefficients for equilibrium distribution of zero divisors of random polynomials (see also [BCM] for the line bundle setting).…”

Section: Introductionmentioning

confidence: 99%

Mass Equidistribution for Random Polynomials

Bayraktar

2019

Potential Anal

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The purpose of this note is to study asymptotic zero distribution of multivariate random polynomials as their degrees grow. For a smooth weight function with super logarithmic growth at infinity, we consider random linear combinations of associated orthogonal polynomials with subgaussian coefficients. This class of probability distributions contains a wide range of random variables including standard Gaussian and all bounded random variables. We prove that for almost every sequence of random polynomials their normalized zero currents become equidistributed with respect to a deterministic extremal current. The main ingredients of the proof are Bergman kernel asymptotics, mass equidistribution of random polynomials and concentration inequalities for subgaussian quadratic forms.

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Asymptotic zero distribution of random orthogonal polynomials

Cited by 12 publications

References 26 publications

An asymptotic expansion for the expected number of real zeros of real random polynomials spanned by OPUC

An asymptotic expansion for the expected number of real zeros of real random polynomials spanned by OPUC

A necessary and sufficient condition for convergence of the zeros of random polynomials

Mass Equidistribution for Random Polynomials

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