English

On the Modified Selberg Integral

Number Theory 2010-06-08 v1

Abstract

We give a kind of \lq \lq approximate majorant principle\rq \rq \thinspace result for the \lq \lq modified Selberg integral\rq \rq, say \modSelf(N,h)\modSel_f(N,h), of essentially bounded f:NRf:\N \rightarrow \R (i.e., bounded by arbitrary small powers); i.e., we get an upper bound, in terms of the modified Selberg integral of a related function FF (with fμFμ|f\ast \mu|\ll F\ast \mu, in the supports intersection), getting a \lq \lq square-root cancellation\rq \rq \thinspace for the error-terms. Here \modSelf(N,h)\modSel_f(N,h) is the mean-square (in N<x2NN<x\le 2N) of the \lq \lq averaged short sum\rq \rq \thinspace of, say, f:=g\1f:=g\ast \1, minus its expected value; i.e., 1hmh0nx<mf(n)Mf(x,h){1\over h}\sum_{m\le h}\sum_{0\le |n-x|<m}f(n)-M_f(x,h), with expected value Mf(x,h)M_f(x,h) (say, hdxg(d)/d\approx h\sum_{d\le x}g(d)/d); so, this mean-square weights, on average, the ff-values in (almost all, i.e. all, but o(N)o(N) possible exceptions) the short intervals [xh,x+h][x-h,x+h], with mild restrictions on \thinspace hh \thinspace (say, \thinspace hh\to \infty \thinspace and \thinspace h=o(N)h=o(N), when \thinspace NN\to \infty).

Keywords

Cite

@article{arxiv.1006.1229,
  title  = {On the Modified Selberg Integral},
  author = {Giovanni Coppola},
  journal= {arXiv preprint arXiv:1006.1229},
  year   = {2010}
}

Comments

6 pages (Plain TeX)

R2 v1 2026-06-21T15:32:45.550Z