Round function

For example, let $M$ be the torus. Let

:$K=(0,2\backslash pi)\backslash times(0,2\backslash pi).\backslash ,$

Then we know that a map

:$X\backslash colon\; K\backslash to\{\backslash mathbb\{R\}\}^3\backslash ,$

given by

:$X(\backslash theta,\backslash phi)=((2+\backslash cos\backslash theta)\backslash cos\backslash phi,(2+\backslash cos\backslash theta)\backslash sin\backslash phi,\backslash sin\backslash theta)\backslash ,$

is a parametrization for almost all of $M$. Now, via the projection $\backslash pi\_3\backslash colon\{\backslash mathbb\{R\}\}^3\backslash to\{\backslash mathbb\{R\}\}$

we get the restriction

:$G=\backslash pi\_3|\_M\backslash colon\; M\backslash to\{\backslash mathbb\{R\}\},\; (\backslash theta,\backslash phi)\; \backslash mapsto\; \backslash sin\; \backslash theta\; \backslash ,$

$G=G(\backslash theta,\backslash phi)=\backslash sin\backslash theta$ is a function whose critical sets are determined by

:$\{\backslash rm\; grad\}\backslash \; G(\backslash theta,\backslash phi)=$

\left({{\partial}G\over {\partial}\theta},{{\partial}G\over {\partial}\phi}\right)\!\left(\theta,\phi\right)=(0,0),\,

this is if and only if $\backslash theta=\{\backslash pi\backslash over\; 2\},\backslash \; \{3\backslash pi\backslash over\; 2\}$.

These two values for $\backslash theta$ give the critical sets

:$X(\{\backslash pi/2\},\backslash phi)=(2\backslash cos\backslash phi,2\backslash sin\backslash phi,1)\backslash ,$

:$X(\{3\backslash pi/2\},\backslash phi)=(2\backslash cos\backslash phi,2\backslash sin\backslash phi,-1)\backslash ,$

which represent two extremal circles over the torus $M$.

Observe that the Hessian for this function is

:$\{\backslash rm\; hess\}(G)=$

\begin{bmatrix}

-\sin\theta & 0 \\ 0 & 0 \end{bmatrix}

which clearly it reveals itself as rank of $\{\backslash rm\; hess\}(G)$ equal to one

at the tagged circles, making the critical point degenerate, that is, showing that the critical points are not isolated.

Mimicking the L–S category theory one can define the round complexity asking for whether or not exist round functions on manifolds and/or for the minimum number of critical loops.

• Siersma and Khimshiasvili, On minimal round functions, Preprint 1118, Department of Mathematics, Utrecht University, 1999, pp. 18.[http://citeseer.ist.psu.edu/287481.html]. An update at [http://igitur-archive.library.uu.nl/math/2001-0628-161022/1118.pdf]

Category:Differential geometry

Category:Geometric topology

Category:Types of functions