Integral of mean curvature function

neelakash

Hello everyone,
I am self teaching some elementary notions of differential geometry. Rather, I should say I am concentrating on mean and gaussian curvature concepts related to a physics application I am interested in. I see one has to evaluate an integral that goes as:

[tex]\int_{\partial\Omega}\kappa\hat{n}\cdot d\vec{r}[/tex]

-where [tex]\hat{n}[/tex] denotes the unit normal vector to the surface [tex]\partial\Omega[/tex]. The integral is done over all the points [tex]\vec{r}[/tex] on the surface. Can anyone tell if there is a prescription to evaluate such integrals as this? If some reference is cited, that will also be helpful.

-Neel

quasar987

You mean "how do we compute this?" ??

If the surface has some nice symmetry spherical or cylindrical symmetry like if it's a conic (ellipsoid, paraboloid, wheteveroid), then you can use the relevant coordinate system (spherical or cylindrical) to integrate.

neelakash

Well, of course you are right...But, what I was expecting is a bit different...I was wondering if this integral could somehow be related to Gaussian curvature. The physics motivation is that for some specific type of surfaces, the integral which apparently may also be written as:
[tex]\int\nabla_{LB}\vec{r}(u,v)\cdot d\vec{r}(u,v)[/tex]

should contain Gaussian curvature. Here [tex]\nabla_{LB}[/tex] is the Laplace-Beltrami operator.

lavinia

I think you need to extend the mean curvature of the surface to the interior of the volume that it bounds. Otherwise I am not sure how you would use Stokes theorem.