A hypothetical way to compute an upper bound for the heights of solutions of a Diophantine equation with a finite number of solutions

Abstract

Let f(n)=1 if n=1, 2(2(n-2)) if n ∈ 2,3,4,5, (2+2(2(n-4)))(2(n-4)) if n ∈ 6,7,8,.... We conjecture that if a system T ⊂eq xi+1=xk, xi · xj=xk: i,j,k ∈ 1,...,n has only finitely many solutions in positive integers x1,...,xn, then each such solution (x1,...,xn) satisfies x1,...,xn ≤ f(n). We prove that the function f cannot be decreased and the conjecture implies that there is an algorithm which takes as input a Diophantine equation, returns an integer, and this integer is greater than the heights of integer (non-negative integer, positive integer, rational) solutions, if the solution set is finite. We show that if the conjecture is true, then this can be partially confirmed by the execution of a brute-force algorithm.