Two terms with known prime divisors adding to a power: REVISED with APPENDICES

Abstract

Let c be a positive odd integer and R a set of n primes coprime with c. We consider equations X + Y = cz in three integer unknowns X, Y, z, where z > 0, Y > X > 0, and the primes dividing XY are precisely those in R. We consider N, the number of solutions of such an equation. Given a solution (X, Y, z), let D be the least positive integer such that (XY/D)1/2 is an integer. Further, let ω be the number of distinct primes dividing c. Standard elementary approaches use an upper bound of 2n for the number of possible D, and an upper bound of 2ω-1 for the number of ideal factorizations of c in the field (-D) which can correspond (in a standard designated way) to a solution in which (XY/D)1/2 ∈ ∫Z, and obtain N 2n+ω-1. Here we improve this by finding an inverse proportionality relationship between a bound on the number of D which can occur in solutions and a bound (independent of D) on the number of ideal factorizations of c which can correspond to solutions for a given D. We obtain N 2n-1+1. The bound is precise for n<4: there are several cases with exactly 2n-1 + 1 solutions. For higher values of n the bound becomes unrealistic, but is nevertheless an improvement on bounds obtained by both elementary and non-elementary methods.