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Special functions, orthogonal polynomials, harmonic analysis, ordinary differential equations (ODE's), differential relations, calculus of variations, approximations, expansions, asymptotics.

1 vote
0 answers
82 views

Weak maximum principle for a perturbation of the Laplacian

This question is motivated by similar considerations for the Kohn-Laplacian in the Heisenberg group, but it seems that I cannot even give an answer in the Euclidean case, so here we go. Suppose that …
an_ordinary_mathematician's user avatar
2 votes
0 answers
180 views

A sharp version of a Tauberian theorem

The following Tauberian theorem is true (see Theorem I.11.1 of ''Tauberian theory: A century of developments''). Let $ a_n $ a sequence of real numbers. If $f(x) = \sum_{n=1}^\infty a_n x^n $ converge …
an_ordinary_mathematician's user avatar
7 votes
3 answers
686 views

A generalization of discrete Hilbert's transform (Montgomery's inequality)

In the paper "Hilbert's inequality", Montgomery and Vaughan proved that a generalization of the discrete Hilbert transform is bounded in $\ell^2$. The inequality reads as follows $$ \Big| \sum_{k\neq …
an_ordinary_mathematician's user avatar
4 votes
1 answer
432 views

Reference or proof of a theorem of L. Fejér on summability of Fourier series

In the article "Ensembles exceptionnels" by A. Beurling, the author cites the following theorem of Fejér: Suppose that a $2\pi$ periodic function $ f $, Lebesgue integrable in $(0,2\pi)$ satisfies the …
an_ordinary_mathematician's user avatar
8 votes

A curious norm related to the L¹ norm

I think $C=2$ is the best constant. Consider $\varepsilon>0$ and let $f,g$ continuous in $[0,1]$ defined as follows. \begin{equation*} f(x) = \begin{cases} -1, & 0\leq x \leq \frac12 - \varepsilon \\ …
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