On my mechanics classes I have a problem: show, that the action for free non-relativistic particle $$S=\int\limits_{t_i}^{t_f}\frac{m\dot{x}^2}{2}dt\tag{1}$$ is really the least (but not maximal).
What I do: $$S=\int\limits_{t_i}^{t_f}\frac{m\dot{x}^2}{2}dt=\frac{mV^2}{2}\int_{t_i}^{t_f}dt=\frac{mV^2}{2}(t_f-t_i).\tag{2}$$ Then $\dot{S}=\frac{mV^2}{2}$ and $\ddot{S}=0$. And for minimality it must be $>0$, but it is just zero. I am confused.
Hints:
You are supposed to show that for arbitrary but FIXED values of $t_i$, $t_f$, $x(t_i)$, $x(t_f)$ (with $t_i< t_f$), that the off-shell action functional $S[x]$ for an arbitrary virtual path $t\mapsto x(t)$ is bigger than the on-shell action $S[x_{\rm cl}]$ for the classical path $t\mapsto x_{\rm cl}(t)$.
Try to show that the difference $S[x]-S[x_{\rm cl}]$ is a manifestly positive functional of the fluctuation $x-x_{\rm cl}$.