In Riemannian or pseudo-Riemannian geometry (in particular the Lorentzian geometry of general relativity), the Levi-Civita connection is the unique affine connection on the tangent bundle of a manifold (i.e. affine connection) that preserves the (pseudo-)Riemannian metric and is torsion-free.
The fundamental theorem of Riemannian geometry states that there is a unique connection which satisfies these properties.
In the theory of Riemannian and pseudo-Riemannian manifolds the term covariant derivative is often used for the Levi-Civita connection. The components (structure coefficients) of this connection with respect to a system of local coordinates are called Christoffel symbols.
The Levi-Civita connection is named after Tullio Levi-Civita, although originally "discovered" by Elwin Bruno Christoffel. Levi-Civita,[1] along with Gregorio Ricci-Curbastro, used Christoffel's symbols[2] to define the notion of parallel transport and explore the relationship of parallel transport with the curvature, thus developing the modern notion of holonomy.[3]
In 1869, Christoffel discovered that the components of the intrinsic derivative of a vector field, upon changing the coordinate system, transform as the components of a contravariant vector. This discovery was the real beginning of tensor analysis.
In 1906, L. E. J. Brouwer was the first mathematician to consider the parallel transport of a vector for the case of a space of constant curvature.[4] [5]
In 1917, Levi-Civita pointed out its importance for the case of a hypersurface immersed in a Euclidean space, i.e., for the case of a Riemannian manifold embedded in a "larger" ambient space. He interpreted the intrinsic derivative in the case of an embedded surface as the tangential component of the usual derivative in the ambient affine space. The Levi-Civita notions of intrinsic derivative and parallel displacement of a vector along a curve make sense on an abstract Riemannian manifold, even though the original motivation relied on a specific embedding
Mn\subsetRn(n+1)/2.
In 1918, independently of Levi-Civita, Jan Arnoldus Schouten obtained analogous results.[6] In the same year, Hermann Weyl generalized Levi-Civita's results.[7] [8]
The metric can take up to two vectors or vector fields as arguments. In the former case the output is a number, the (pseudo-)inner product of and . In the latter case, the inner product of is taken at all points on the manifold so that defines a smooth function on . Vector fields act (by definition) as differential operators on smooth functions. In local coordinates
(x1,\ldots,xn)
X(f)=
| ||||
| X |
f=
| i\partial | |
| X | |
| i |
f
where Einstein's summation convention is used.
\nabla
\nablag=0
X
Y
\nablaXY-\nablaYX=[X,Y]
[X,Y]
X
Y
Condition 1 above is sometimes referred to as compatibility with the metric, and condition 2 is sometimes called symmetry, cf. Do Carmo's text.[9]
See main article: Fundamental theorem of Riemannian geometry. Theorem Every (pseudo-)Riemannian manifold
(M,g)
\nabla
Proof:To prove uniqueness, unravel the definition of the action of a connection on tensors to find
Xl(g(Y,Z)r)=(\nablaXg)(Y,Z)+g(\nablaXY,Z)+g(Y,\nablaXZ)
\nabla
Xl(g(Y,Z)r)=g(\nablaXY,Z)+g(Y,\nablaXZ)
g
Xl(g(Y,Z)r)+Yl(g(Z,X)r)-Zl(g(Y,X)r)=g(\nablaXY+\nablaYX,Z)+g(\nablaXZ-\nablaZX,Y)+g(\nablaYZ-\nablaZY,X)
2g(\nablaXY,Z)-g([X,Y],Z)+g([X,Z],Y)+g([Y,Z],X)
g(\nablaXY,Z)=\tfrac{1}{2}\{Xl(g(Y,Z)r)+Yl(g(Z,X)r)-Zl(g(X,Y)r)+g([X,Y],Z)-g([Y,Z],X)-g([X,Z],Y)\}
Z
g
\nabla
To prove existence, note that for given vector field
X
Y
Z
g
\nablaXY
X,Y,Z
f
g(\nablaX(Y1+Y2),Z)=g(\nablaXY1,Z)+g(\nablaXY2,Z)
g(\nablaX(fY),Z)=X(f)g(Y,Z)+fg(\nablaXY,Z)
g(\nablaXY,Z)+g(\nablaXZ,Y)=Xl(g(Y,Z)r)
g(\nablaXY,Z)-g(\nablaYX,Z)=g([X,Y],Z).
With minor variation, the same proof shows that there is a unique connection that is compatible with the metric and has prescribed torsion.
Let
\nabla
x1,\ldots,xn
\partial1,\ldots,\partialn
\nablaj
| \nabla | |
| \partialj |
| l | |
| \Gamma | |
| jk |
\nabla
\nablaj\partialk=
| l | |
| \Gamma | |
| jk |
\partiall
The Christoffel symbols conversely define the connection
\nabla
\begin{align} \nablaXY&=
| \nabla | |||||||
|
(Yk\partialk) \\&=
| k\partial | |
| X | |
| k) |
\ &=
| k)\partial | |
| X | |
| k |
+
| k\nabla | |
| Y | |
| j\partial |
kr)\ &=
| k)\partial | |
| X | |
| k |
+Yk\Gamma
| l | |
| jk |
\partiallr) \ &=
| l) | |
| X | |
| j(Y |
+Yk\Gamma
| l | |
| jk |
r)\partiall \end{align}
(\nablajY)l=
| l | |
| \partial | |
| jY |
+
| l | |
| \Gamma | |
| jk |
Yk
\nabla
\partialil(g(\partialj,\partialk)r) =g(\nablai\partialj,\partialk)+g(\partialj,\nablai\partialk) =
| l | |
| g(\Gamma | |
| ij |
\partiall,\partialk)+g(\partialj,
| l\partial | |
| \Gamma | |
| l) |
\partialigjk=
| l | |
| \Gamma | |
| ij |
glk+
| l | |
| \Gamma | |
| ik |
gjl.
\nablaj\partialk-\nablak\partialj=
| l | |
| (\Gamma | |
| jk |
-
| l | |
| \Gamma | |
| kj |
)\partiall=[\partialj,\partialk]=0.
| l | |
| \Gamma | |
| jk |
=
| l | |
| \Gamma | |
| kj |
As one checks by taking for
X,Y,Z
\partialj,\partialk,\partiall
| l | |
| \Gamma | |
| jk |
=\tfrac{1}{2}glr\left(\partialkgrj+\partialjgrk-\partialrgjk\right)
where as usual
gij
gkl
The Levi-Civita connection (like any affine connection) also defines a derivative along curves, sometimes denoted by .
Given a smooth curve on and a vector field along its derivative is defined by
DtV=\nabla
|
V.
Formally, is the pullback connection on the pullback bundle .
In particular,
| \gamma(t) |
| \nabla | |||||
|
| \gamma |
(t)
| \gamma |
\left(\gamma*\nabla\right)
| \gamma |
\equiv0.
If the covariant derivative is the Levi-Civita connection of a certain metric, then the geodesics for the connection are precisely those geodesics of the metric that are parametrised proportionally to their arc length.
In general, parallel transport along a curve with respect to a connection defines isomorphisms between the tangent spaces at the points of the curve. If the connection is a Levi-Civita connection, then these isomorphisms are orthogonal – that is, they preserve the inner products on the various tangent spaces.
R2\backslash\{0,0\}
ds2=dx2+dy2=dr2+r2d\theta2
ds2=dr2+d\theta2
dr=
| xdx+ydy | |
| \sqrt{x2+y2 |
d\theta=
| xdy-ydx | |
| x2+y2 |
dr2+d\theta2=
| (xdx+ydy)2 | |
| x2+y2 |
+
| (xdy-ydx)2 | |
| (x2+y2)2 |
Warning: This is parallel transport on the punctured plane along the unit circle, not parallel transport on the unit circle. Indeed, in the first image, the vectors fall outside of the tangent space to the unit circle.
Let be the usual scalar product on . Let be the unit sphere in . The tangent space to at a point is naturally identified with the vector subspace of consisting of all vectors orthogonal to . It follows that a vector field on can be seen as a map, which satisfies
Denote as the differential of the map at the point . Then we have:
In fact, this connection is the Levi-Civita connection for the metric on inherited from . Indeed, one can check that this connection preserves the metric.
If the metric
g
\hatg=e2\gammag
gradg(\gamma)
\gamma
g
d\gamma
gik(\partiali\gamma)\partialk
\widehat\nabla
g(Y,Y)
z,\barz
dzd\barz
\gamma=ln(2)-ln(1+z\barz)
d\gamma=-(1+z\barz)-1(\barzdz+zd{\barz})
gradEuc(\gamma)=-(1+z\barz)-1(\barz\partialz+z\partial\bar)