I don't know if this is the kind of answer you expect, but:

In the hyperbolic space of dimension $n+1$ one naturally gets all $n$-dimensional constant curvature geometries.

 - spheres (points at distance $\le r$ from a given point) inherit their spherical $n$-dimensional geometry. I'm not sure what the curvature is as a function of $r$, but it tends to $0$ resp. $\infty$ when the radius tends to $\infty$ resp. $0$.
 - horospheres inherit the Euclidean $n$-dimensional metric. Recall that a horofunction is a limit $h$ of functions $x\mapsto d(x,x_n)-d(x_0,x_n)$ for some sequence $x_n$ tending to infinity, and a horosphere is $\{x:h(x)=0\}$ for some horofunction $h$.
 - for two distinct points $x_1,x_2$, the set of $x$ such that $d(x,x_1)=d(x,x_2)$ inherits the $n$-dimensional hyperbolic geometry.