In differential geometry, the Laplace–Beltrami operator is a generalization of the Laplace operator to functions defined on submanifolds in Euclidean space and, even more generally, on Riemannian and pseudo-Riemannian manifolds. It is named after Pierre-Simon Laplace and Eugenio Beltrami.
For any twice-differentiable real-valued function f defined on Euclidean space Rn, the Laplace operator (also known as the Laplacian) takes f to the divergence of its gradient vector field, which is the sum of the n pure second derivatives of f with respect to each vector of an orthonormal basis for Rn. Like the Laplacian, the Laplace–Beltrami operator is defined as the divergence of the gradient, and is a linear operator taking functions into functions. The operator can be extended to operate on tensors as the divergence of the covariant derivative. Alternatively, the operator can be generalized to operate on differential forms using the divergence and exterior derivative. The resulting operator is called the Laplace–de Rham operator (named after Georges de Rham).
The Laplace–Beltrami operator, like the Laplacian, is the (Riemannian) divergence of the (Riemannian) gradient:
\Deltaf={\rmdiv}(\nablaf).
Suppose first that M is an oriented Riemannian manifold. The orientation allows one to specify a definite volume form on M, given in an oriented coordinate system xi by
\operatorname{vol}n:=\sqrt{|g|} dx1\wedge … \wedgedxn
where is the absolute value of the determinant of the metric tensor, and the dxi are the 1-forms forming the dual frame to the frame
\partiali:=
| \partial | |
| \partialxi |
TM
\wedge
The divergence of a vector field
X
\nabla ⋅ X
(\nabla ⋅ X)\operatorname{vol}n:=LX\operatorname{vol}n
where LX is the Lie derivative along the vector field X. In local coordinates, one obtains
\nabla ⋅ X=
| 1 | |
| \sqrt{|g| |
\langle ⋅ , ⋅ \rangle
\langle\operatorname{grad}f(x),vx\rangle=df(x)(vx)
for all vectors vx anchored at point x in the tangent space TxM of the manifold at point x. Here, dƒ is the exterior derivative of the function ƒ; it is a 1-form taking argument vx. In local coordinates, one has
\left(\operatorname{grad}f\right)i=\partialif=gij\partialjf
where gij are the components of the inverse of the metric tensor, so that with δik the Kronecker delta.
Combining the definitions of the gradient and divergence, the formula for the Laplace–Beltrami operator applied to a scalar function ƒ is, in local coordinates
\Deltaf=
| 1 | |
| \sqrt{|g| |
If M is not oriented, then the above calculation carries through exactly as presented, except that the volume form must instead be replaced by a volume element (a density rather than a form). Neither the gradient nor the divergence actually depends on the choice of orientation, and so the Laplace–Beltrami operator itself does not depend on this additional structure.
The exterior derivative
d
-\nabla
f
\intMdf(X)\operatorname{vol}n=-\intMf\nabla ⋅ X\operatorname{vol}n
where the last equality is an application of Stokes' theorem. Dualizing gives
for all compactly supported functions
f
h
As a consequence, the Laplace–Beltrami operator is negative and formally self-adjoint, meaning that for compactly supported functions
f
h
\intMf\Deltah\operatorname{vol}n=-\intM\langledf,dh\rangle\operatorname{vol}n=\intMh\Deltaf\operatorname{vol}n.
Because the Laplace–Beltrami operator, as defined in this manner, is negative rather than positive, often it is defined with the opposite sign.
Let M denote a compact Riemannian manifold without boundary. We want to consider the eigenvalue equation,
-\Deltau=λu,
u
λ
λ
M
λ
λ=0
-\Delta
λ\geq0
u
M
dV=\operatorname{vol}n
-\intM\Delta
| 2 dV | |
| u u dV=λ\int | |
| Mu |
M
-\intM\Deltau u dV=\intM|\nablau|2 dV
\intM|\nabla
| 2 dV | |
| u| | |
| Mu |
λ\geq0
A fundamental result of André Lichnerowicz[1] states that: Given a compact n-dimensional Riemannian manifold with no boundary with
n\geq2
\operatorname{Ric}(X,X)\geq\kappag(X,X),\kappa>0,
g( ⋅ , ⋅ )
X
M
λ1
λ1\geq
| n | |
| n-1 |
\kappa.
Sn
S2
λ1
x1,x2,x3
R3
S2
(\theta,\phi)
S2
x3=\cos\phi=u1,
-\Delta
| S2 |
u1=2u1
Conversely it was proved by Morio Obata,[2] that if the n-dimensional compact Riemannian manifold without boundary were such that for the first positive eigenvalue
λ1
| λ | ||||
|
\kappa,
| ||||
| S |
| \sqrt{ | n-1 |
| \kappa |
Cn.
The Laplace–Beltrami operator can be written using the trace (or contraction) of the iterated covariant derivative associated with the Levi-Civita connection. The Hessian (tensor) of a function
f
\displaystyleHessf\in\Gamma(T*M ⊗ T*M)
Hessf:=\nabla2f\equiv\nabla\nablaf\equiv\nabladf
where df denotes the (exterior) derivative of a function f.
Let Xi be a basis of tangent vector fields (not necessarily induced by a coordinate system). Then the components of Hess f are given by
(Hessf)ij=Hessf(Xi,Xj)=
| \nabla | |
| Xi |
| \nabla | |
| Xj |
f-
| \nabla | |||||||
|
f
This is easily seen to transform tensorially, since it is linear in each of the arguments Xi, Xj. The Laplace–Beltrami operator is then the trace (or contraction) of the Hessian with respect to the metric:
\displaystyle\Deltaf:=tr\nabladf\inCinfty(M)
More precisely, this means
\displaystyle\Deltaf(x)=
| n | |
| \sum | |
| i=1 |
\nabladf(Xi,Xi)
or in terms of the metric
\Deltaf=\sumijgij(Hessf)ij.
In abstract indices, the operator is often written
\Deltaf=\nablaa\nablaaf
provided it is understood implicitly that this trace is in fact the trace of the Hessian tensor.
Because the covariant derivative extends canonically to arbitrary tensors, the Laplace–Beltrami operator defined on a tensor T by
\DeltaT=gij\left(
| \nabla | |
| Xi |
| \nabla | |
| Xj |
T-
| \nabla | |||||||
|
T\right)
More generally, one can define a Laplacian differential operator on sections of the bundle of differential forms on a pseudo-Riemannian manifold. On a Riemannian manifold it is an elliptic operator, while on a Lorentzian manifold it is hyperbolic. The Laplace–de Rham operator is defined by
\Delta=d\delta+\deltad=(d+\delta)2,
where d is the exterior derivative or differential and δ is the codifferential, acting as on k-forms, where ∗ is the Hodge star. The first order operator
d+\delta
When computing the Laplace–de Rham operator on a scalar function f, we have, so that
\Deltaf=\deltadf.
Up to an overall sign, the Laplace–de Rham operator is equivalent to the previous definition of the Laplace–Beltrami operator when acting on a scalar function; see the proof for details. On functions, the Laplace–de Rham operator is actually the negative of the Laplace–Beltrami operator, as the conventional normalization of the codifferential assures that the Laplace–de Rham operator is (formally) positive definite, whereas the Laplace–Beltrami operator is typically negative. The sign is merely a convention, and both are common in the literature. The Laplace–de Rham operator differs more significantly from the tensor Laplacian restricted to act on skew-symmetric tensors. Apart from the incidental sign, the two operators differ by a Weitzenböck identity that explicitly involves the Ricci curvature tensor.
Many examples of the Laplace–Beltrami operator can be worked out explicitly.
In the usual (orthonormal) Cartesian coordinates xi on Euclidean space, the metric is reduced to the Kronecker delta, and one therefore has
|g|=1
\Deltaf=
| 1 | |
| \sqrt{|g| |
which is the ordinary Laplacian. In curvilinear coordinates, such as spherical or cylindrical coordinates, one obtains alternative expressions.
Similarly, the Laplace–Beltrami operator corresponding to the Minkowski metric with signature is the d'Alembertian.
The spherical Laplacian is the Laplace–Beltrami operator on the -sphere with its canonical metric of constant sectional curvature 1. It is convenient to regard the sphere as isometrically embedded into Rn as the unit sphere centred at the origin. Then for a function f on Sn-1, the spherical Laplacian is defined by
\Delta
| Sn-1 |
f(x)=\Deltaf(x/|x|)
\Delta
\Deltaf=r1-n
| \partial | |
| \partialr |
\left(rn-1
| \partialf | |
| \partialr |
\right)+r-2\Delta
| Sn-1 |
f.
More generally, one can formulate a similar trick using the normal bundle to define the Laplace–Beltrami operator of any Riemannian manifold isometrically embedded as a hypersurface of Euclidean space.
One can also give an intrinsic description of the Laplace–Beltrami operator on the sphere in a normal coordinate system. Let be spherical coordinates on the sphere with respect to a particular point p of the sphere (the "north pole"), that is geodesic polar coordinates with respect to p. Here ϕ represents the latitude measurement along a unit speed geodesic from p, and ξ a parameter representing the choice of direction of the geodesic in Sn-1. Then the spherical Laplacian has the form:
\Delta
| Sn-1 |
f(\xi,\phi)=(\sin\phi)2-n
| \partial | |
| \partial\phi |
\left((\sin\phi)n-2
| \partialf | |
| \partial\phi |
\right)+(\sin\phi)-2\Delta\xif
\Delta\xi
\Delta
| S2 |
f(\theta,\phi)=(\sin\phi)-1
| \partial | \left(\sin\phi | |
| \partial\phi |
| \partialf | |
| \partial\phi |
\right)+(\sin\phi)-2
| \partial2 | |
| \partial\theta2 |
f
A similar technique works in hyperbolic space. Here the hyperbolic space Hn-1 can be embedded into the n dimensional Minkowski space, a real vector space equipped with the quadratic form
q(x)=
| 2 | |
| x | |
| 1 |
-
| 2- … | |
| x | |
| 2 |
-
| 2. | |
| x | |
| n |
Hn=\{x\midq(x)=1,x1>1\}.
\Delta
| Hn-1 |
f=\left.\Boxf\left(x/q(x)1/2\right)\right|
| Hn-1 |
f(x/q(x)1/2)
\Box=
| \partial2 | ||||||||
|
- … -
| \partial2 | ||||||||
|
.
The operator can also be written in polar coordinates. Let be spherical coordinates on the sphere with respect to a particular point p of Hn-1 (say, the center of the Poincaré disc). Here t represents the hyperbolic distance from p and ξ a parameter representing the choice of direction of the geodesic in Sn-2. Then the hyperbolic Laplacian has the form:
\Delta
| Hn-1 |
f(t,\xi)=\sinh(t)2-n
| \partial | |
| \partialt |
\left(\sinh(t)n-2
| \partialf | |
| \partialt |
\right)+\sinh(t)-2\Delta\xif
\Delta\xi
\Delta
| H2 |
f(r,\theta)=\sinh(r)-1
| \partial | \left(\sinh(r) | |
| \partialr |
| \partialf | |
| \partialr |
\right)+\sinh(r)-2
| \partial2 | |
| \partial\theta2 |
f