Elementary solutions of ordinary tropical differential equations, and vanishing orders of solutions of algebraic differential equations

Abstract

Our aim is to use tropical differential algebra to systematically build a combinatorial basis for the study of the set of (formal) power series solutions to nonlinear algebraic ordinary differential equations (over C) expanded around the point t0=0∈C, which may also be effectively computed using standard tropical algebra. This paper is divided into two parts. First, given an ordinary tropical differential equation in one differential variable P=P(y) of (differential) order k, we study the sets SolB[\![tΓ]\!],k(P)⊃ μ(SolB[\![tΓ]\!](P)\!) of tropical elementary k-solutions and minimal tropical solutions, respectively; we show that these two sets bear many similarities. We do this for tropical solutions y=φ(t)∈ B[\![tΓ]\!] (with coefficients in the boolean semifield B) of P having support in different relevant submonoids Γ of (R,+,0). Then, given an ordinary algebraic differential equation P (with meromorphic coefficients in one differential variable P=P(y) and of differential order k), we consider the set S(P,0):=ordt(SolC[\![tR]\!](P)\!)⊂R of t-adic orders of formal Hahn solutions of P, which is an algebraic object that gives information about the nature of the germs of solutions of P at the point t0=0∈C. We show that this set is contained in the set of t-adic orders of Hahn elementary k-solutions of its tropicalization P=trop(P), this is S(P,0)⊂ ordt(SolB[\![tR]\!],k(P)). In most cases, the set SolB[\![tR]\!],k(P) is a finite family of univariate tropical polynomials.