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Complex Approximations, Orthogonal Polynomials and Applications Workshop
June 7, 2021 11:15–11:40, Sochi
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Multiplicity of zeros of polynomials
V. Totik Bolyai Institute, University of Szeged
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Abstract:
In 1940 Paul Erdős and Paul Turán proved their basic
discrepancy estimate stating that if a monic polynomial of degree $n$
with real zeros has
supremum norm $\|P_n\|_{[-1,1]}\le M_n2^{-n}$ on $[-1,1]$, then the normalized distribution of their
zeros is closer than $C\sqrt {(\log M_n)/n}$ to the arcsine (Chebyshev) distribution.
This implies that the highest multiplicity of the zeros is
$\le C\sqrt {(\log M_n) n}$. In particular, if the norm is $O(1)2^{-n}$, then the highest multiplicity
is $O(\sqrt{n})$, and Erdős and Turán conjectured that
$\sqrt n$ order multiplicity can be achieved under this condition.
In this talk
sharp bounds are given for the highest multiplicity
of zeros of polynomials in terms of their norm
on smooth Jordan curves and arcs. The results solve the
just mentioned problem of Erdős and Turán. In addition, their
bound on the multiplicities for the case $[-1,1]$ will be made more precise by comparing the norm not
to $2^{-n}$ but to the theoretical minimum $2^{1-n}$ (note that, by Chebyshev's theorem, $M_n\ge 2$, so
from the Erdős–Turán estimate one cannot get a smaller bound for the multiplicity than
$O(\sqrt n)$, while if one can prove the bound $O(\sqrt {(\log N_n) n})$ from
$\|P_n\|_{[-1,1]}\le N_n2^{1-n}$,
then this gives $o(\sqrt{n})$ as soon as $N_n=1+o(1)$). We shall also discuss why there are no
such results on non-smooth curves and arcs, or on sets consisting of more than one component.
The proofs use potential theory and a Faber-type modification of a result of G. Halász.
Language: English
Website:
https://us02web.zoom.us/j/8618528524?pwd=MmxGeHRWZHZnS0NLQi9jTTFTTzFrQT09
* Zoom conference ID: 861 852 8524 , password: caopa |
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