The reason is that the pointer that is behind (increased more slowly) needs to be increased to get it out of any branches coming off the cycle.

Eg. Edges A => B, B => C, C => A, D => B, E => D.

Suppose both pointers start at E. Then if you don't change one pointer, the other will go E => D => B => C => A => B => C => ..., and never get to E.

When others say you won't get the same algorithmic complexity, they mean you will have to try start from every single vertex (which is slower). With the fast/slow pointer method, you only have to try starting from each "component" of the graph ONCE. A component is all the vertices connected to each other. Separate components means that the vertices are not connected by edges.

By increasing the slow pointer, it will also get into the A => B => C cycle.

And it will never miss, because the effective difference in the change of pointers is only 1. ie. If the fast pointer is catching up to the slow pointer, the distance between them only changes by 1 each iteration. So eventually the distance will reach 0.