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Gauss–Codazzi equations

The equations were originally discovered in the context of surfaces in three-dimensional Euclidean space. In this context, the first equation, often called the Gauss equation (after its discoverer Carl Friedrich Gauss), says that the Gauss curvature of the surface, at any given point, is dictated by the derivatives of the Gauss map at that point, as encoded by the second fundamental form.^[2] The second equation, called the Codazzi equationorCodazzi-Mainardi equation, states that the covariant derivative of the second fundamental form is fully symmetric. It is named for Gaspare Mainardi (1856) and Delfino Codazzi (1868–1869), who independently derived the result,^[3] although it was discovered earlier by Karl Mikhailovich Peterson.^[4][5]

Formal statement[edit]

Let ${\displaystyle i\colon M\subset P}$ be an n-dimensional embedded submanifold of a Riemannian manifold P of dimension ${\displaystyle n+p}$. There is a natural inclusion of the tangent bundleofM into that of P by the pushforward, and the cokernel is the normal bundleofM:

${\displaystyle 0\rightarrow T_{x}M\rightarrow T_{x}P|_{M}\rightarrow T_{x}^{\perp }M\rightarrow 0.}$

The metric splits this short exact sequence, and so

${\displaystyle TP|_{M}=TM\oplus T^{\perp }M.}$

Relative to this splitting, the Levi-Civita connection ${\displaystyle \nabla '}$ofP decomposes into tangential and normal components. For each ${\displaystyle X\in TM}$ and vector field YonM,

${\displaystyle \nabla '_{X}Y=\top \left(\nabla '_{X}Y\right)+\bot \left(\nabla '_{X}Y\right).}$

Let

${\displaystyle \nabla _{X}Y=\top \left(\nabla '_{X}Y\right),\quad \alpha (X,Y)=\bot \left(\nabla '_{X}Y\right).}$

The Gauss formula^[6] now asserts that ${\displaystyle \nabla _{X}}$ is the Levi-Civita connection for M, and ${\displaystyle \alpha }$ is a symmetric vector-valued form with values in the normal bundle. It is often referred to as the second fundamental form.

An immediate corollary is the Gauss equation for the curvature tensor. For ${\displaystyle X,Y,Z,W\in TM}$,

${\displaystyle \langle R'(X,Y)Z,W\rangle =\langle R(X,Y)Z,W\rangle +\langle \alpha (X,Z),\alpha (Y,W)\rangle -\langle \alpha (Y,Z),\alpha (X,W)\rangle }$

where ${\displaystyle R'}$ is the Riemann curvature tensorofP and R is that of M.

The Weingarten equation is an analog of the Gauss formula for a connection in the normal bundle. Let ${\displaystyle X\in TM}$ and ${\displaystyle \xi }$ a normal vector field. Then decompose the ambient covariant derivative of ${\displaystyle \xi }$ along X into tangential and normal components:

${\displaystyle \nabla '_{X}\xi =\top \left(\nabla '_{X}\xi \right)+\bot \left(\nabla '_{X}\xi \right)=-A_{\xi }($X)+D_{X}(\xi ).}

Then

1. Weingarten's equation: ${\displaystyle \langle A_{\xi }X,Y\rangle =\langle \alpha (X,Y),\xi \rangle }$
2. D_X is a metric connection in the normal bundle.

There are thus a pair of connections: ∇, defined on the tangent bundle of M; and D, defined on the normal bundle of M. These combine to form a connection on any tensor product of copies of TM and T^⊥M. In particular, they defined the covariant derivative of ${\displaystyle \alpha }$:

${\displaystyle \left({\tilde {\nabla }}_{X}\alpha \right)(Y,Z)=D_{X}\left(\alpha (Y,Z)\right)-\alpha \left(\nabla _{X}Y,Z\right)-\alpha \left(Y,\nabla _{X}Z\right).}$

The Codazzi–Mainardi equationis

${\displaystyle \bot \left(R'(X,Y)Z\right)=\left({\tilde {\nabla }}_{X}\alpha \right)(Y,Z)-\left({\tilde {\nabla }}_{Y}\alpha \right)(X,Z).}$

Since every immersion is, in particular, a local embedding, the above formulas also hold for immersions.

Gauss–Codazzi equations in classical differential geometry[edit]

Statement of classical equations[edit]

In classical differential geometry of surfaces, the Codazzi–Mainardi equations are expressed via the second fundamental form (L, M, N):

${\displaystyle L_{v}-M_{u}=L\Gamma ^{1}{}_{12}+M\left({\Gamma ^{2}}_{12}-{\Gamma ^{1}}_{11}\right)-N{\Gamma ^{2}}_{11}}$

${\displaystyle M_{v}-N_{u}=L\Gamma ^{1}{}_{22}+M\left({\Gamma ^{2}}_{22}-{\Gamma ^{1}}_{12}\right)-N{\Gamma ^{2}}_{12}}$

The Gauss formula, depending on how one chooses to define the Gaussian curvature, may be a tautology. It can be stated as

${\displaystyle K={\frac {LN-M^{2}}{eg-f^{2}}},}$

where (e, f, g) are the components of the first fundamental form.

Derivation of classical equations[edit]

Consider a parametric surface in Euclidean 3-space,

${\displaystyle \mathbf {r} (u,v)=(x(u,v),y(u,v),z(u,v))}$

where the three component functions depend smoothly on ordered pairs (u,v) in some open domain U in the uv-plane. Assume that this surface is regular, meaning that the vectors r_u and r_v are linearly independent. Complete this to a basis {r_u,r_v,n}, by selecting a unit vector n normal to the surface. It is possible to express the second partial derivatives of r (vectors of ${\displaystyle \mathbb {R^{3}} }$) with the Christoffel symbols and the elements of the second fundamental form. We choose the first two components of the basis as they are intrinsic to the surface and intend to prove intrinsic property of the Gaussian curvature. The last term in the basis is extrinsic.

${\displaystyle \mathbf {r} _{uu}={\Gamma ^{1}}_{11}\mathbf {r} _{u}+{\Gamma ^{2}}_{11}\mathbf {r} _{v}+L\mathbf {n} }$

${\displaystyle \mathbf {r} _{uv}={\Gamma ^{1}}_{12}\mathbf {r} _{u}+{\Gamma ^{2}}_{12}\mathbf {r} _{v}+M\mathbf {n} }$

${\displaystyle \mathbf {r} _{vv}={\Gamma ^{1}}_{22}\mathbf {r} _{u}+{\Gamma ^{2}}_{22}\mathbf {r} _{v}+N\mathbf {n} }$

Clairaut's theorem states that partial derivatives commute:

${\displaystyle \left(\mathbf {r} _{uu}\right)_{v}=\left(\mathbf {r} _{uv}\right)_{u}}$

If we differentiate r_uu with respect to v and r_uv with respect to u, we get:

${\displaystyle \left({\Gamma ^{1}}_{11}\right)_{v}\mathbf {r} _{u}+{\Gamma ^{1}}_{11}\mathbf {r} _{uv}+\left({\Gamma ^{2}}_{11}\right)_{v}\mathbf {r} _{v}+{\Gamma ^{2}}_{11}\mathbf {r} _{vv}+L_{v}\mathbf {n} +L\mathbf {n} _{v}}$${\displaystyle =\left({\Gamma ^{1}}_{12}\right)_{u}\mathbf {r} _{u}+{\Gamma ^{1}}_{12}\mathbf {r} _{uu}+\left(\Gamma _{12}^{2}\right)_{u}\mathbf {r} _{v}+{\Gamma ^{2}}_{12}\mathbf {r} _{uv}+M_{u}\mathbf {n} +M\mathbf {n} _{u}}$

Now substitute the above expressions for the second derivatives and equate the coefficients of n:

${\displaystyle M{\Gamma ^{1}}_{11}+N{\Gamma ^{2}}_{11}+L_{v}=L{\Gamma ^{1}}_{12}+M{\Gamma ^{2}}_{12}+M_{u}}$

Rearranging this equation gives the first Codazzi–Mainardi equation.

The second equation may be derived similarly.

Mean curvature[edit]

Let M be a smooth m-dimensional manifold immersed in the (m + k)-dimensional smooth manifold P. Let ${\displaystyle e_{1},e_{2},\ldots ,e_{k}}$ be a local orthonormal frame of vector fields normal to M. Then we can write,

${\displaystyle \alpha (X,Y)=\sum _{j=1}^{k}\alpha _{j}(X,Y)e_{j}.}$

If, now, ${\displaystyle E_{1},E_{2},\ldots ,E_{m}}$ is a local orthonormal frame (of tangent vector fields) on the same open subset of M, then we can define the mean curvatures of the immersion by

${\displaystyle H_{j}=\sum _{i=1}^{m}\alpha _{j}(E_{i},E_{i}).}$

In particular, if M is a hypersurface of P, i.e. ${\displaystyle k=1}$, then there is only one mean curvature to speak of. The immersion is called minimal if all the ${\displaystyle H_{j}}$ are identically zero.

Observe that the mean curvature is a trace, or average, of the second fundamental form, for any given component. Sometimes mean curvature is defined by multiplying the sum on the right-hand side by ${\displaystyle 1/m}$.

We can now write the Gauss–Codazzi equations as

${\displaystyle \langle R'(X,Y)Z,W\rangle =\langle R(X,Y)Z,W\rangle +\sum _{j=1}^{k}\left(\alpha _{j}(X,Z)\alpha _{j}(Y,W)-\alpha _{j}(Y,Z)\alpha _{j}(X,W)\right).}$

Contracting the ${\displaystyle Y,Z}$ components gives us

${\displaystyle \operatorname {Ric} '(X,W)=\operatorname {Ric} (X,W)+\sum _{j=1}^{k}\langle R'(X,e_{j})e_{j},W\rangle +\sum _{j=1}^{k}\left(\sum _{i=1}^{m}\alpha _{j}(X,E_{i})\alpha _{j}(E_{i},W)-H_{j}\alpha _{j}(X,W)\right).}$

When M is a hypersurface, this simplifies to

${\displaystyle \operatorname {Ric} '(X,W)=\operatorname {Ric} (X,W)+\langle R'(X,n)n,W\rangle +\sum _{i=1}^{m}h(X,E_{i})h(E_{i},W)-Hh(X,W)}$

where ${\displaystyle n=e_{1},}$ ${\displaystyle h=\alpha _{1}}$ and ${\displaystyle H=H_{1}}$. In that case, one more contraction yields,

${\displaystyle R'=R+2\operatorname {Ric} '(n,n)+\|h\|^{2}-H^{2}}$

where ${\displaystyle R'}$ and ${\displaystyle R}$ are the scalar curvatures of P and M respectively, and

${\displaystyle \|h\|^{2}=\sum _{i,j=1}^{m}h(E_{i},E_{j})^{2}.}$

If${\displaystyle k>1}$, the scalar curvature equation might be more complicated.

We can already use these equations to draw some conclusions. For example, any minimal immersion^[7] into the round sphere ${\displaystyle x_{1}^{2}+x_{2}^{2}+\cdots +x_{m+k+1}^{2}=1}$ must be of the form

${\displaystyle \Delta x_{j}+\lambda x_{j}=0}$

where ${\displaystyle j}$ runs from 1 to ${\displaystyle m+k+1}$ and

${\displaystyle \Delta =\sum _{i=1}^{m}\nabla _{E_{i}}\nabla _{E_{i}}}$

is the LaplacianonM, and ${\displaystyle \lambda >0}$ is a positive constant.

See also[edit]

• Darboux frame

Notes[edit]

References[edit]

Historical references

• Bonnet, Ossian (1867), "Memoire sur la theorie des surfaces applicables sur une surface donnee", Journal de l'École Polytechnique, 25: 31–151
• Codazzi, Delfino (1868–1869), "Sulle coordinate curvilinee d'una superficie dello spazio", Ann. Mat. Pura Appl., 2: 101–19, doi:10.1007/BF02419605, S2CID 177803350
• Gauss, Carl Friedrich (1828), "Disquisitiones Generales circa Superficies Curvas" [General Discussions about Curved Surfaces], Comm. Soc. Gott. (in Latin), 6 ("General Discussions about Curved Surfaces")
• Ivanov, A.B. (2001) [1994], "Peterson–Codazzi equations", Encyclopedia of Mathematics, EMS Press
• Kline, Morris (1972), Mathematical Thought from Ancient to Modern Times, Oxford University Press, ISBN 0-19-506137-3
• Mainardi, Gaspare (1856), "Su la teoria generale delle superficie", Giornale Dell' Istituto Lombardo, 9: 385–404
• Peterson, Karl Mikhailovich (1853), Über die Biegung der Flächen, Doctoral thesis, Dorpat University.

Textbooks

• do Carmo, Manfredo P. Differential geometry of curves & surfaces. Revised & updated second edition. Dover Publications, Inc., Mineola, NY, 2016. xvi+510 pp. ISBN 978-0-486-80699-0, 0-486-80699-5
• do Carmo, Manfredo Perdigão. Riemannian geometry. Translated from the second Portuguese edition by Francis Flaherty. Mathematics: Theory & Applications. Birkhäuser Boston, Inc., Boston, MA, 1992. xiv+300 pp. ISBN 0-8176-3490-8
• Kobayashi, Shoshichi; Nomizu, Katsumi. Foundations of differential geometry. Vol. II. Interscience Tracts in Pure and Applied Mathematics, No. 15 Vol. II Interscience Publishers John Wiley & Sons, Inc., New York-London-Sydney 1969 xv+470 pp.
• O'Neill, Barrett. Semi-Riemannian geometry. With applications to relativity. Pure and Applied Mathematics, 103. Academic Press, Inc. [Harcourt Brace Jovanovich, Publishers], New York, 1983. xiii+468 pp. ISBN 0-12-526740-1
• Toponogov, Victor Andreevich (2006). Differential geometry of curves and surfaces: A concise guide. Boston: Birkhäuser. ISBN 978-0-8176-4384-3.

Articles

• Takahashi, Tsunero (1966), "Minimal immersions of Riemannian manifolds", Journal of the Mathematical Society of Japan, 18 (4), doi:10.2969/jmsj/01840380, S2CID 122849496
• Simons, James. Minimal varieties in riemannian manifolds. Ann. of Math. (2) 88 (1968), 62–105.
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External links[edit]

• Peterson–Mainardi–Codazzi Equations – from Wolfram MathWorld
• Peterson–Codazzi Equations