An explicit generating function arising in counting binomial coefficients divisible by powers of primes
Abstract
For a prime and nonnegative integers and let be the number of entries in the -th row of Pascal's triangle that are exactly divisible by . Moreover, for a finite sequence in we denote by the number of times that appears as a factor (contiguous subsequence) of the base- expansion of . It follows from the work of Barat and Grabner (Digital functions and distribution of binomial coefficients, J. London Math. Soc. (2) 64(3), 2001), that is given by a polynomial in the variables , where are certain finite words in , and each variable is set to . This was later made explicit by Rowland (The number of nonzero binomial coefficients modulo , J. Comb. Number Theory 3(1), 2011), independently from Barat and Grabner's work, and Rowland described and implemented an algorithm computing these polynomials . In this paper, we express the coefficients of using generating functions, and we prove that these generating functions can be determined explicitly by means of a recurrence relation. Moreover, we prove that is uniquely determined, and we note that the proof of our main theorem also provides a new proof of its existence. Besides providing insight into the structure of the polynomials , our results allow us to compute them in a very efficient way.
Keywords
Cite
@article{arxiv.1604.07089,
title = {An explicit generating function arising in counting binomial coefficients divisible by powers of primes},
author = {Lukas Spiegelhofer and Michael Wallner},
journal= {arXiv preprint arXiv:1604.07089},
year = {2017}
}
Comments
30 pages