Everyday I walk to class and I have to walk through a sequence of sprinklers. I usually watch them for a second and try to plan a path in which I never have to stop or back track and will not get wet. It would be even better if I could maintain a constant speed.
Question
If we consider sprinkler system to be an $n \times n$ lattice where the water extends a length $L$ from the lattice point, has random initial direction and each rotates at a constant angular velocity $v$, what is the smallest $L$ and $n$ such that there exists no smooth, path from $(0,0)$ (or more generally, from any $(a,b)$) to $(n,n)$ and $\frac{dx}{dt} \ge 0$, $\frac{dy}{dt} \ge 0$? Or, what conditions must we impose on this system to guarantee a solution (other than having them all rotating the same and having me sprint arbitrarily quickly)?
Example sprinkler system:
Observations
Any case where $L \le .5$ is trivial since there is always a solution by following the outside of the circles formed by the sprinklers. Similarly, $L<\sqrt{2}n$ for any $n$. Of course there will not always be such an $n$ and $L$ like in the $2 \times 2$ case where there is a solution for all $L$ and any initial orientation. I feel like if $n$ and $L$ are sufficiently large, there will be no solution since you will eventually be caught inside of a polygon that is shrinking, but I do not have bounds on this conjecture.