English

Combinatorial congruences modulo prime powers

Number Theory 2007-07-25 v5 Combinatorics

Abstract

Let p be any prime, and let a and n be nonnegative integers. Let rZr\in Z and f(x)Z[x]f(x)\in Z[x]. We establish the congruence pdegfk=r(modpa)(nk)(1)kf((kr)/pa)=0(modpi=a[n/pi])p^{\deg f}\sum_{k=r(mod p^a)}\binom{n}{k}(-1)^k f((k-r)/p^a) =0 (mod p^{\sum_{i=a}^{\infty}[n/p^i]}) (motivated by a conjecture arising from algebraic topology), and obtain the following vast generalization of Lucas' theorem: If a is greater than one, and l,s,tl,s,t are nonnegative integers with s,t<ps,t<p, then 1[n/pa1]!k=r(modpa)(pn+spk+t)(1)pk((kr)/pa1)l=1[n/pa1]!k=r(modpa)(nk)(st)(1)k((kr)/pa1)l(modp).\frac{1}{[n/p^{a-1}]!} \sum_{k=r(mod p^a)} \binom{pn+s}{pk+t}(-1)^{pk}((k-r)/p^{a-1})^l =\frac {1}{[n/p^{a-1}]!} \sum_{k=r(mod p^a)}\binom{n}{k}\binom{s}{t}(-1)^k((k-r)/p^{a-1})^l (mod p). We also present an application of the first congruence to Bernoulli polynomials, and apply the second congruence to show that a p-adic order bound given by the authors in a previous paper can be attained when p=2.

Keywords

Cite

@article{arxiv.math/0508087,
  title  = {Combinatorial congruences modulo prime powers},
  author = {Zhi-Wei Sun and Donald M. Davis},
  journal= {arXiv preprint arXiv:math/0508087},
  year   = {2007}
}