Arithmetic properties of the Taylor coefficients of differentially algebraic power series

Abstract

Let f=Σn=0∞ fn xn ∈ Q[[x] be a solution of an algebraic differential equation Q(x,y(x), …, y(k)(x))=0, where Q is a multivariate polynomial with coefficients in Q. The sequence (fn)n 0 satisfies a non-linear recurrence, whose expression involves a polynomial M of degree s. When the equation is linear, M is its indicial polynomial at the origin. We show that when M is split over Q, there exist two positive integers δ and such that the denominator of fn divides δn+1( n+)!2s for all n 0\ , generalizing a well-known property when the equation is linear. This proves in this case a strong form of a conjecture of Mahler that P\'olya--Popken's upper bound nO(n(n)) for the denominator of fn is not optimal. This also enables us to make Sibuya and Sperber's bound fnv eO(n), for all finite places v of Q, explicit in this case. Our method is completely effective and rests upon a detailed p-adic analysis of the above mentioned non-linear recurrences. Finally, we present various examples of differentially algebraic functions for which the associated polynomial M is split over Q, among which are Weierstra' elliptic function, solutions of Painlev\'e equations, and Lagrange's solution to Kepler's equation.

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