For a $2n$ Minkowski space $M^n$ the dimension of the null geodesics is $2n-3$. It is naturally a contact manifold (for general Lorentzian space in general relativity you need a condition for the space of geodesics to be a manifold, but that's another story). 

This is how you can see it: consider the space of all parametrized geodesics in $M^n$, that is the space of curves $t \mapsto x + tv$, this space is equivalent to $TM$ ($x$ and $v$), dimension $2n$. Now identify two lines $c : t \mapsto x + tv$ and $c' : t \mapsto x' + tv'$ having the same trajectory, that is the same image $\{x+tv \mid t \in {\bf R}\}$, that gives you the space of un-parametrized geodesics. But two such lines have the same image iff $c'(t) = c(at+b)$ where $a \in {\bf R}$ and $a \neq 0$ and $b \in {\bf R}$. Thus these un-parametrized geodesics are the orbits of the affine group ${\rm Aff}({\bf R})$. That gives you $x'=x+bv$ and $v' = av$. The quotient $TM/{\rm Aff}({\bf R})$ is equivalent to $TS^{n-1}$. Now in $TM$ the space of null geodesics is the $2n-1$ subspace defined by $v \cdot v = 0$ (hypersurface), and you see that the affine group act on this subspace,and its action is still free, then the dimension of your quotient, the space of null un-parametrized geodesics, is $2n-3$. And indeed for $n=4$ you get 5, what you were looking for.

P.S. Long time ago, I wrote a small text on this construction that I never published. But I recently put it on line. It was a letter to a colleague of mine. You can find the manuscript [here][1]  


  [1]: http://math.huji.ac.il/~piz/Site/The%20Articles/A4DF9FB4-E2B8-4F1E-A18A-85B473E73E43.html