English

On the arithmetic Hilbert depth

Number Theory 2024-02-20 v2 Combinatorics

Abstract

Let h:ZZ0h:\mathbb Z \to \mathbb Z_{\geq 0} be a nonzero function with h(k)=0h(k)=0 for k0k\ll 0. We define the Hilbert depth of hh by hdepth(h)=max{d  :  jk(1)kj(djkj)h(j)0 for all kd}\operatorname{hdepth}(h)=\max\{d\;:\; \sum_{j\leq k} (-1)^{k-j}\binom{d-j}{k-j}h(j)\geq 0\text{ for all }k\leq d\}. We show that hdepth(h)\operatorname{hdepth}(h) is a natural generalization for the Hilbert depth of a subposet P2[n]\operatorname{P}\subset 2^{[n]} and we prove some basic properties of it. Given h(j)={ajn+b,j00,j<0h(j)=\begin{cases} aj^n+b,& j\geq 0 \\ 0, & j<0 \end{cases}, with a,b,na,b,n positive integers, we compute hdepth(h)\operatorname{hdepth}(h) for n=1,2n=1,2 and we give upper bounds for hdepth(h)\operatorname{hdepth}(h) for n3n\geq 3. More generally, if h(j)={P(j),j00,j<0h(j)=\begin{cases} P(j),& j\geq 0 \\ 0,& j<0 \end{cases}, where P(j)P(j) is a polynomial of degree nn, with non-negative integer coefficients, and P(0)>0P(0)>0, we show that hdepth(h)2n+1\operatorname{hdepth}(h)\leq 2^{n+1}.

Keywords

Cite

@article{arxiv.2309.10521,
  title  = {On the arithmetic Hilbert depth},
  author = {Silviu Balanescu and Mircea Cimpoeas},
  journal= {arXiv preprint arXiv:2309.10521},
  year   = {2024}
}

Comments

17 pages; we changed the expression "quasi depth" with the one more appropriate, Hilbert depth; also, other minor corrections

R2 v1 2026-06-28T12:25:58.254Z