Roots of Formal Power Series and New Theorems on Riordan Group Elements

Abstract

Elements of the Riordan group R over a field F of characteristic zero are infinite lower triangular matrices which are defined in terms of pairs of formal power series. We wish to bring to the forefront, as a tool in the theory of Riordan groups, the use of multiplicative roots a(x)1n of elements a(x) in the ring of formal power series over F . Using roots, we give a Normal Form for non-constant formal power series, we prove a surprising simple Composition-Cancellation Theorem and apply this to show that, for a major class of Riordan elements (i.e., for non-constant g(x) and appropriate F(x)), only one of the two basic conditions for checking that (g(x), \, F(x)) has order n in the group R actually needs to be checked. Using all this, our main result is to generalize C. Marshall [Congressus Numerantium, 229 (2017), 343-351] and prove: Given non-constant g(x) satisfying necessary conditions, there exists a unique F(x), given by an explicit formula, such that (g(x), \, F(x)) is an involution in R. Finally, as examples, we apply this theorem to ``aerated" series h(x) = g(xq),\ q\ odd, to find the unique K(x) such that (h(x), K(x)) is an involution.