Let ${\displaystyle M,N}$  be connected, complete Riemannian manifolds. We consider the problem of isometrically mapping a small patch on ${\displaystyle M}$  to a small patch on ${\displaystyle N}$ .

Let ${\displaystyle x\in M,y\in N}$ , and let

${\displaystyle I:T_{x}M\rightarrow T_{y}N}$ 

be a linear isometry. This can be interpreted as isometrically mapping an infinitesimal patch (the tangent space) at ${\displaystyle x}$  to an infinitesimal patch at ${\displaystyle y}$ . Now we attempt to extend it to a finite (rather than infinitesimal) patch.

For sufficiently small ${\displaystyle r>0}$ , the exponential maps

${\displaystyle \exp _{x}:B_{r}(x)\subset T_{x}M\rightarrow M,\exp _{y}:B_{r}(y)\subset T_{y}N\rightarrow N}$ 

are local diffeomorphisms. Here, ${\displaystyle B_{r}(x)}$  is the ball centered on ${\displaystyle x}$  of radius ${\displaystyle r.}$  One then defines a diffeomorphism ${\displaystyle f:B_{r}(x)\rightarrow B_{r}(y)}$  by

${\displaystyle f=\exp _{y}\circ I\circ \exp _{x}^{-1}.}$ 

When is ${\displaystyle f}$  an isometry? Intuitively, it should be an isometry if it satisfies the two conditions:

• It is a linear isometry at the tangent space of every point on ${\displaystyle B_{r}(x)}$ , that is, it is an isometry on the infinitesimal patches.
• It preserves the curvature tensor at the tangent space of every point on ${\displaystyle B_{r}(x)}$ , that is, it preserves how the infinitesimal patches fit together.

If ${\displaystyle f}$  is an isometry, it must preserve the geodesics. Thus, it is natural to consider the behavior of ${\displaystyle f}$  as we transport it along an arbitrary geodesic radius ${\displaystyle \gamma :\left[0,T\right]\rightarrow B_{r}(x)\subset M}$  starting at ${\displaystyle \gamma (0)=x}$ . By property of the exponential mapping, ${\displaystyle f}$  maps it to a geodesic radius of ${\displaystyle B_{r}(y)}$  starting at ${\displaystyle f(\gamma )(0)=y}$ ,.

Let ${\displaystyle P_{\gamma }(t)}$  be the parallel transport along ${\displaystyle \gamma }$  (defined by the Levi-Civita connection), and ${\displaystyle P_{f(\gamma )(t)}}$  be the parallel transport along ${\displaystyle f(\gamma )}$ , then we have the mapping between infinitesimal patches along the two geodesic radii:

${\displaystyle I_{\gamma }(t)=P_{f(\gamma )(t)}\circ I\circ P_{\gamma (t)}^{-1}:T_{\gamma (t)}M\rightarrow T_{f(\gamma (t))}N\quad {\text{ for all }}t\in [0,T]}$ 

The original theorem proven by Cartan is the local version of the Cartan–Ambrose–Hicks theorem.

${\displaystyle f}$  is an isometry if and only if for all geodesic radii ${\displaystyle \gamma :\left[0,T\right]\rightarrow B_{r}(x)\subset M}$  with ${\displaystyle \gamma (0)=x}$ , and all ${\displaystyle t\in [0,T],X,Y,Z\in T_{\gamma (t)}M}$ , we have ${\displaystyle I_{\gamma }(t)(R(X,Y,Z))={\overline {R}}(I_{\gamma }(t)(X),I_{\gamma }(t)(Y),I_{\gamma }(t)(Z))}$  where ${\displaystyle R,{\overline {R}}}$  are Riemann curvature tensors of ${\displaystyle M,N}$ .

In words, it states that ${\displaystyle f}$  is an isometry if and only if the only way to preserve its infinitesimal isometry also preserves the Riemannian curvature.

Note that ${\displaystyle f}$  generally does not have to be a diffeomorphism, but only a locally isometric covering map. However, ${\displaystyle f}$  must be a global isometry if ${\displaystyle N}$  is simply connected.

Theorem: For Riemann curvature tensors ${\displaystyle R,{\overline {R}}}$  and all broken geodesics (a broken geodesic is a curve that is piecewise geodesic) ${\displaystyle \gamma :\left[0,T\right]\rightarrow M}$  with ${\displaystyle \gamma (0)=x}$ ,

${\displaystyle I_{\gamma }(t)(R(X,Y,Z))={\overline {R}}(I_{\gamma }(t)(X),I_{\gamma }(t)(Y),I_{\gamma }(t)(Z))}$ 

for all ${\displaystyle t\in [0,T],X,Y,Z\in T_{\gamma (t)}M}$ .

Then, if two broken geodesics beginning in ${\displaystyle x}$  have the same endpoint, then the corresponding broken geodesics (mapped by ${\displaystyle I_{\gamma }}$ ) in ${\displaystyle N}$  also have the same end point. So there exists a map

${\displaystyle F:M\rightarrow N}$ 

by mapping the broken geodesic endpoints in ${\displaystyle M}$ to the corresponding geodesic endpoints in ${\displaystyle N}$ .

The map ${\displaystyle F:M\rightarrow N}$  is a locally isometric covering map.

If ${\displaystyle N}$  is also simply connected, then ${\displaystyle F}$  is an isometry.

A Riemannian manifold is called locally symmetric if its Riemann curvature tensor is invariant under parallel transport:

${\displaystyle \nabla R=0.}$ 

A simply connected Riemannian manifold is locally symmetric if it is a symmetric space.

From the Cartan–Ambrose–Hicks theorem, we have:

Theorem: Let ${\displaystyle M,N}$  be connected, complete, locally symmetric Riemannian manifolds, and let ${\displaystyle M}$  be simply connected. Let their Riemann curvature tensors be ${\displaystyle R,{\overline {R}}}$ . Let ${\displaystyle x\in M,y\in N}$  and

${\displaystyle I:T_{x}M\rightarrow T_{y}N}$ 

be a linear isometry with ${\displaystyle I(R(X,Y,Z))={\overline {R}}(I(X),I(Y),I(Z))}$ . Then there exists a locally isometric covering map

${\displaystyle F:M\rightarrow N}$ 

with ${\displaystyle F(x)=y}$  and ${\displaystyle D_{x}F=I}$ .

Corollary: Any complete locally symmetric space is of the form ${\displaystyle M/\gamma }$  for a symmetric space ${\displaystyle M}$ and ${\displaystyle \gamma \subset Isom(M)}$  is a discrete subgroup of isometries of ${\displaystyle M}$ .

As an application of the Cartan–Ambrose–Hicks theorem, any simply connected, complete Riemannian manifold with constant sectional curvature ${\displaystyle \in \{+1,0,-1\}}$  is respectively isometric to the n-sphere ${\displaystyle S^{n}}$ , the n-Euclidean space ${\displaystyle E^{n}}$ , and the n-hyperbolic space ${\displaystyle \mathbb {H} ^{n}}$ .