What is the class of differentiable n-dimensional manifolds that allow a differential structure, in which all transition maps are isometric? Note that isometric must be overlapping pieces of charts only; however, mapping from charts to manifold can be arbitrary non-linear function.
I know such manifolds exist. For example:
Trivial example: a graph of a differentiable function is such manifold.
A circle: I can construct an atlas of two charts: upper and lower parts that overlap by $\varepsilon$. Since charts overlap by intervals of equal length $\varepsilon$, I can build isometric transition map.
A 2D torus ($\mathbb{T}^2$): I can build 4 charts that overlap by small rectangles. These rectangles can be made isometric to one another. Also, places where all 4 charts overlap can be made isometric as well.
This construction seems to fail for a 2D sphere. So, I'm wondering which class of n-dimensional differentiable manifolds satisfies given constraints on differential structure?
EDIT:
In mathematical terms: Which differentiable manifolds allow differential structure $\big\{\big(\phi_\alpha, U_\alpha\big)\big\}_{\alpha \in \mathcal{A}}$ such that: $\forall \alpha, \beta \in \mathcal{A}$, if $U_\alpha \bigcap U_\beta \not= \emptyset$, then the restriction $\phi_\alpha \circ \phi^{-1}_\beta\big|_{\phi_\beta (U_\alpha \cap U_\beta)}$ is an isometric map between sets $\phi_\beta (U_\alpha \cap U_\beta)$ and $\phi_\alpha (U_\alpha \cap U_\beta)$ in $\mathbb{R}^n$?
Note that neither $\phi_\alpha$ nor $\phi_\beta$ need not be isometric maps. Also note that $U_\alpha$ and $U_\beta$ need not be isometric to each other as well.