Isoparametric manifold: Difference between revisions

Latest revision as of 19:34, 2 February 2014

In Riemannian geometry, the Rauch comparison theorem, named after Harry Rauch who proved it in 1951, is a fundamental result which relates the sectional curvature of a Riemannian manifold to the rate at which geodesics spread apart. Intuitively, it states that for positive curvature, geodesics tend to converge, while for negative curvature, geodesics tend to spread. This theorem is formulated using Jacobi fields to measure the variation in geodesics.

Statement of the Theorem

Let $M$ , $\tilde{M}$ be Riemannian manifolds, let $γ : [0, T] \to M$ and $\tilde{γ} : [0, T] \to \tilde{M}$ be unit speed geodesic segments such that $\tilde{γ} (0)$ has no conjugate points along $\tilde{γ}$ , and let $J$ , $\tilde{J}$ be normal Jacobi fields along $γ$ and $\tilde{γ}$ such that $J (0) = \tilde{J} (0) = 0$ and $| D_{t} J (0) | = | {\tilde{D}}_{t} \tilde{J} (0) |$ . Suppose that the sectional curvatures of $M$ and $\tilde{M}$ satisfy $K (Π) \leq \tilde{K} (\tilde{Π})$ whenever $Π \subset T_{γ (t)} M$ is a 2-plane containing $\dot{γ} (t)$ and $\tilde{Π} \subset T_{\tilde{γ} (t)} \tilde{M}$ is a 2-plane containing $\dot{\tilde{γ}} (t)$ . Then $| J (t) | \geq | \tilde{J} (t) |$ for all $t \in [0, T]$ .

References

do Carmo, M.P. Riemannian Geometry, Birkhäuser, 1992.
Lee, J. M., Riemannian Manifolds: An Introduction to Curvature, Springer, 1997.

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+In [[Riemannian geometry]], the '''Rauch comparison theorem''', named after [[Harry Rauch]] who proved it in 1951, is a fundamental result which relates the [[sectional curvature]] of a [[Riemannian manifold]] to the rate at which [[geodesic]]s spread apart.  Intuitively, it states that for positive curvature, geodesics tend to converge, while for negative curvature, geodesics tend to spread.  This theorem is formulated using [[Jacobi field]]s to measure the variation in geodesics.
+==Statement of the Theorem==
+Let <math>M</math>, <math>\widetilde{M}</math> be Riemannian manifolds, let <math>\gamma : [0, T] \to M</math> and <math>\widetilde{\gamma} : [0,T] \to \widetilde{M}</math> be unit speed [[geodesic]] segments such that <math>\widetilde{\gamma}(0)</math> has no [[conjugate points]] along <math>\widetilde{\gamma}</math>, and let <math>J</math>, <math>\widetilde{J}</math> be normal Jacobi fields along <math>\gamma</math> and <math>\widetilde{\gamma}</math> such that <math>J(0) = \widetilde{J}(0) = 0</math> and <math>|D_t J(0)| = |\widetilde{D}_t \widetilde{J}(0)|</math>. Suppose that the sectional curvatures of <math>M</math> and <math>\widetilde{M}</math> satisfy <math>K(\Pi) \leq \widetilde{K}(\widetilde{\Pi})</math> whenever <math>\Pi \subset T_{\gamma(t)} M</math> is a 2-plane containing <math>\dot{\gamma}(t)</math> and <math>\widetilde{\Pi} \subset T_{\tilde{\gamma}(t)} \widetilde{M}</math> is a 2-plane containing <math>\dot{\widetilde{\gamma}}(t)</math>. Then <math>|J(t)| \geq |\widetilde{J}(t)|</math> for all <math>t \in [0, T]</math>.
+==See also==
+*[[Theorem of Toponogov]]
+==References==
+*do Carmo, M.P. ''Riemannian Geometry'', Birkhäuser, 1992.
+* Lee, J. M., ''Riemannian Manifolds: An Introduction to Curvature'', Springer, 1997.
+[[Category:Theorems in Riemannian geometry]]
+{{differential-geometry-stub}}

Isoparametric manifold: Difference between revisions

Latest revision as of 19:34, 2 February 2014

Statement of the Theorem

See also

References

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