Jacobi field

In Riemannian geometry, a Jacobi field is a vector field along a geodesic ${\displaystyle \gamma }$ in a Riemannian manifold describing the difference between the geodesic and an "infinitesimally close" geodesic. In other words, the Jacobi fields along a geodesic form the tangent space to the geodesic in the space of all geodesics. They are named after Carl Jacobi.

Jacobi fields can be obtained in the following way: Take a smooth one parameter family of geodesics ${\displaystyle {\gamma }_{\tau }}$ with ${\displaystyle {\gamma }_0=\gamma }$, then

${\displaystyle J(t)={\frac{\partial {\gamma }_{\tau }(t)}{\partial \tau }|}_{\tau =0}}$

is a Jacobi field, and describes the behavior of the geodesics in an infinitesimal neighborhood of a given geodesic ${\displaystyle \gamma }$.

A vector field J along a geodesic ${\displaystyle \gamma }$ is said to be a Jacobi field if it satisfies the Jacobi equation:

${\displaystyle \frac{D^2}{d{t}^2}J(t)+R(J(t),\dot{\gamma }(t))\dot{\gamma }(t)=0,}$

where D denotes the covariant derivative with respect to the Levi-Civita connection, R the Riemann curvature tensor, ${\displaystyle \dot{\gamma }(t)=d\gamma (t)/dt}$ the tangent vector field, and t is the parameter of the geodesic. On a complete Riemannian manifold, for any Jacobi field there is a family of geodesics ${\displaystyle {\gamma }_{\tau }}$ describing the field (as in the preceding paragraph).

The Jacobi equation is a linear, second order ordinary differential equation; in particular, values of ${\displaystyle J}$ and ${\displaystyle \frac{D}{dt}J}$ at one point of ${\displaystyle \gamma }$ uniquely determine the Jacobi field. Furthermore, the set of Jacobi fields along a given geodesic forms a real vector space of dimension twice the dimension of the manifold.

As trivial examples of Jacobi fields one can consider ${\displaystyle \dot{\gamma }(t)}$ and ${\displaystyle t\dot{\gamma }(t)}$. These correspond respectively to the following families of reparametrizations: ${\displaystyle {\gamma }_{\tau }(t)=\gamma (\tau +t)}$ and ${\displaystyle {\gamma }_{\tau }(t)=\gamma ((1+\tau )t)}$.

Any Jacobi field ${\displaystyle J}$ can be represented in a unique way as a sum ${\displaystyle T+I}$, where ${\displaystyle T=a\dot{\gamma }(t)+bt\dot{\gamma }(t)}$ is a linear combination of trivial Jacobi fields and ${\displaystyle I(t)}$ is orthogonal to ${\displaystyle \dot{\gamma }(t)}$, for all ${\displaystyle t}$. The field ${\displaystyle I}$ then corresponds to the same variation of geodesics as ${\displaystyle J}$, only with changed parametrizations.

On a unit sphere, the geodesics through the North pole are great circles. Consider two such geodesics ${\displaystyle {\gamma }_0}$ and ${\displaystyle {\gamma }_{\tau }}$ with natural parameter, ${\displaystyle t\in [0,\pi ]}$, separated by an angle ${\displaystyle \tau }$. The geodesic distance

${\displaystyle d({\gamma }_0(t),{\gamma }_{\tau }(t))}$

is

${\displaystyle d({\gamma }_0(t),{\gamma }_{\tau }(t))={\sin }^{-1}(\sin t\sin \tau \sqrt{1+{\cos }^{2}t{\tan }^2(\tau /2)}).}$

Computing this requires knowing the geodesics. The most interesting information is just that

${\displaystyle d({\gamma }_0(\pi ),{\gamma }_{\tau }(\pi ))=0}$, for any ${\displaystyle \tau }$.

Instead, we can consider the derivative with respect to ${\displaystyle \tau }$ at ${\displaystyle \tau =0}$:

${\displaystyle \frac{\partial }{\partial \tau }{|}_{\tau =0}d({\gamma }_0(t),{\gamma }_{\tau }(t))=|J(t)|=\sin t.}$

Notice that we still detect the intersection of the geodesics at ${\displaystyle t=\pi }$. Notice further that to calculate this derivative we do not actually need to know

${\displaystyle d({\gamma }_0(t),{\gamma }_{\tau }(t))}$,

rather, all we need do is solve the equation

${\displaystyle y^{″}+y=0}$,

for some given initial data.

Jacobi fields give a natural generalization of this phenomenon to arbitrary Riemannian manifolds.

Let ${\displaystyle e_1(0)=\dot{\gamma }(0)/|\dot{\gamma }(0)|}$ and complete this to get an orthonormal basis ${\displaystyle \{e_i(0)\}}$ at ${\displaystyle T_{\gamma (0)}M}$. Parallel transport it to get a basis ${\displaystyle \{e_i(t)\}}$ all along ${\displaystyle \gamma }$. This gives an orthonormal basis with ${\displaystyle e_1(t)=\dot{\gamma }(t)/|\dot{\gamma }(t)|}$. The Jacobi field can be written in co-ordinates in terms of this basis as ${\displaystyle J(t)=y^k(t)e_k(t)}$ and thus

${\displaystyle \frac{D}{dt}J=\sum _k\frac{d{y}^k}{dt}{e}_k(t),\frac{D^2}{d{t}^2}J=\sum _k\frac{d^2{y}^k}{d{t}^2}{e}_k(t),}$

and the Jacobi equation can be rewritten as a system

${\displaystyle \frac{d^2{y}^k}{d{t}^2}+|\dot{\gamma }{|}^2\sum _j{y}^j(t)⟨R(e_j(t),e_1(t))e_1(t),e_k(t)⟩=0}$

for each ${\displaystyle k}$. This way we get a linear ordinary differential equation (ODE). Since this ODE has smooth coefficients we have that solutions exist for all ${\displaystyle t}$ and are unique, given ${\displaystyle y^k(0)}$ and ${\displaystyle y^k\text{'}(0)}$, for all ${\displaystyle k}$.

Consider a geodesic ${\displaystyle \gamma (t)}$ with parallel orthonormal frame ${\displaystyle e_i(t)}$, ${\displaystyle e_1(t)=\dot{\gamma }(t)/|\dot{\gamma }|}$, constructed as above.

• The vector fields along ${\displaystyle \gamma }$ given by ${\displaystyle \dot{\gamma }(t)}$ and ${\displaystyle t\dot{\gamma }(t)}$ are Jacobi fields.
• In Euclidean space (as well as for spaces of constant zero sectional curvature) Jacobi fields are simply those fields linear in ${\displaystyle t}$.
• For Riemannian manifolds of constant negative sectional curvature ${\displaystyle -k^2}$, any Jacobi field is a linear combination of ${\displaystyle \dot{\gamma }(t)}$, ${\displaystyle t\dot{\gamma }(t)}$ and ${\displaystyle \exp (\pm kt)e_i(t)}$, where ${\displaystyle i>1}$.
• For Riemannian manifolds of constant positive sectional curvature ${\displaystyle k^2}$, any Jacobi field is a linear combination of ${\displaystyle \dot{\gamma }(t)}$, ${\displaystyle t\dot{\gamma }(t)}$, ${\displaystyle \sin (kt)e_i(t)}$ and ${\displaystyle \cos (kt)e_i(t)}$, where ${\displaystyle i>1}$.
• The restriction of a Killing vector field to a geodesic is a Jacobi field in any Riemannian manifold.

• Conjugate points
• Geodesic deviation equation
• Rauch comparison theorem
• N-Jacobi field

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