Solvability of meromorphic equations in elementary functions

Abstract

An equation f(x)=a, where f is a complex meromorphic function and a∈C is a parameter, is solvable in elementary functions if the inverse map x=f-1(a) can be expressed as a finite composition of arithmetic operations (addition, subtraction, multiplication, and division), the exponential function, the complex logarithm, and constants. Specific functions such as x - x, x + x, xx have been proven to be unsolvable by Kanel-Belov, Malistov, Zaytsev, while almost all entire surjective functions of at most exponential growth have been covered by Zelenko. All these rely on one-dimensional topological Galois theory, developed by Khovanskii. We generalize to provide a proof for the unsolvability of all elementary meromorphic functions f such that the derivative of f has infinitely many roots xi and the set of distinct values f(xi) is infinite.