Divisibility Properties of Integer Sequences

Abstract

A sequence of nonzero integers f = (f1, f2, …) is ``binomid'' if every f-binomid coefficient [\! arrayc n \\ k array\! ]f is an integer. Those terms are the generalized binomial coefficients: \[ [\! arrayc n \\ k array\! ]f \ = \ fnfn-1·s fn-k+1 fkfk-1·s f1 . \] Let (f) be the infinite triangle with those numbers as entries. When I = (1, 2, 3, …) then (I) is Pascal's Triangle so that I is binomid. Surprisingly, every row and column of Pascal's Triangle is also binomid. For any f, each row and column of (f) generates its own triangle and all those triangles fit together to form the ``Binomid Pyramid'' BP(f). Sequence f is ``binomid at every level'' if all entries of BP(f) are integers. We prove that several familiar sequences have that property, including the Lucas sequences. In particular, I = (1, 2, 3, … ), the sequence of Fibonacci numbers, and (2n - 1)n 1 are binomid at every level.