The 2-color Rado number of $x_1+x_2+...+x_{m-1}=ax_m$

Abstract: In 1982, Beutelspacher and Brestovansky proved that for every integer $m\geq 3,$ the 2-color Rado number of the equation $$x_1+x_2+...+x_{m-1}=x_m$$ is $m^2-m-1.$ In 2008, Schaal and Vestal proved that, for every $m\geq 6,$ the 2-color Rado number of $$x_1+x_2+...+x_{m-1}=2x_m$$ is $\lceil \frac{m-1}{2}\lceil\frac{m-1}{2}\rceil\rceil.$ Here we prove that, for every integer $a\geq 3$ and every $m\geq 2a^2-a+2$, the 2-color Rado number of $$x_1+x_2+...+x_{m-1}=ax_m$$ is $\lceil\frac{m-1}{a}\lceil\frac{m-1}{a}\rceil\rceil.$ For the case $a=3,$ we show that our formula gives the Rado number for all $m\geq 7,$ and we determine the Rado number for all $m\geq 3.$