English

Gaussian Riemann Derivatives

Classical Analysis and ODEs 2022-11-18 v1

Abstract

J. Marcinkiewicz and A. Zygmund proved in 1936 that, for all functions ff and points xx, the existence of the nnth Peano derivative f(n)(x)f_{(n)}(x) is equivalent to the existence of both f(n1)(x)f_{(n-1)}(x) and the nnth generalized Riemann derivative D~nf(x)\widetilde{D}_nf(x), based at x,x+h,x+2h,x+22h,,x+2n1hx,x+h,x+2h,x+2^2h,\ldots ,x+2^{n-1}h. For q0,±1q\neq 0,\pm 1, we introduce: two qq-analogues of the nn-th Riemann derivative Dnf(x){D}_nf(x) of~ff at~xx, the nn-th Gaussian Riemann derivatives qDnf(x){_q}{D}_nf(x) and qDˉnf(x){_q}{\bar D}_nf(x) are the nn-th generalized Riemann derivatives based at x,x+h,x+qh,x+q2h,,x+qn1hx,x+h,x+qh,x+q^2h,\ldots ,x+q^{n-1}h and x+h,x+qh,x+q2h,,x+qnhx+h,x+qh,x+q^2h,\ldots ,x+q^{n}h; and one analog of the nn-th symmetric Riemann derivative Dnsf(x){D}_n^sf(x), the nn-th symmetric Gaussian Riemann derivative qDnsf(x){_q}{D}_n^sf(x) is the nn-th generalized Riemann derivative based at (x),x±h,x±qh,x±q2h,,x±qm1h(x),x\pm h,x\pm qh,x\pm q^2h,\ldots ,x\pm q^{m-1}h, where m=(n+1)/2m=\lfloor (n+1)/2\rfloor and~(x)(x) means that xx is taken only for nn even. We provide the exact expressions for their associated differences in terms of Gaussian binomial coefficients; we show that the two nnth Gaussian derivatives satisfy the above classical theorem, and that the nnth symmetric Gaussian derivative satisfies a symmetric version of the theorem; and we conjecture that these two results are false for every larger classes of generalized Riemann derivatives, thereby extending two recent conjectures by Ash and Catoiu, both of which we update by answering them in a few cases.

Cite

@article{arxiv.2211.09209,
  title  = {Gaussian Riemann Derivatives},
  author = {J. M. Ash and S. Catoiu and H. Fejzic},
  journal= {arXiv preprint arXiv:2211.09209},
  year   = {2022}
}
R2 v1 2026-06-28T06:04:41.450Z