On determination of Zero-sum -generalized Schur Numbers for some linear equations

Abstract

Let r, m and k≥ 2 be positive integers such that r k and let v ∈ [ 0, k-12r ] be any integer. For any integer ∈ [1, k] and ε ∈ \0,1\, we let Ev(, ε) be the linear homogeneous equation defined by Ev(, ε): x1 + ·s + xk-(rv+ε) =xk-(rv+ε-1) +·s+ xk. We denote the number Sz,m(, ε)(k;r;v), which is defined to be the least positive integer t such that for any m-coloring : [1, t] \0, 1,…,m-1\, there exists a solution (x1, x2, …, xk) to the equation Ev(,ε) that satisfies the r-zero-sum condition, namely, Σi=1k(xi) 0r. In this article, we completely determine the constant Sz, 2(k,1)(k;r;0), Sz, m(k-1,1)(k;r;0), Sz, 2(1,1)(k;2;1) and Sz, r(1,0)(k;r;v). Also, we prove upper bound for the constants Sz,2(2,1)(k;2;0) and Sz,2(1,1)(k;2;v).