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Cohn-Vossen's inequality

April 11, 2024

In differential geometry, Cohn-Vossen's inequality, named after Stefan Cohn-Vossen, relates the integral of Gaussian curvature of a non-compact surface to the Euler characteristic. It is akin to the Gauss–Bonnet theorem for a compact surface.

A divergent path within a Riemannian manifold is a smooth curve in the manifold that is not contained within any compact subset of the manifold. A complete manifold is one in which every divergent path has infinite length with respect to the Riemannian metric on the manifold. Cohn-Vossen's inequality states that in every complete Riemannian 2-manifold S with finite total curvature and finite Euler characteristic, we have[1]

where K is the Gaussian curvature, dA is the element of area, and χ is the Euler characteristic.

Examples edit

  • If S is a compact surface (without boundary), then the inequality is an equality by the usual Gauss–Bonnet theorem for compact manifolds.
  • If S has a boundary, then the Gauss–Bonnet theorem gives
 
where   is the geodesic curvature of the boundary, and its integral the total curvature which is necessarily positive for a boundary curve, and the inequality is strict. (A similar result holds when the boundary of S is piecewise smooth.)
  • If S is the plane R2, then the curvature of S is zero, and χ(S) = 1, so the inequality is strict: 0 < 2π.

Notes and references edit

  1. ^ Robert Osserman, A Survey of Minimal Surfaces, Courier Dover Publications, 2002, page 86.
  • Cohn-Vossen, Stefan (1935). "Kürzeste Wege und Totalkrümmung auf Flächen". Compositio Mathematica. 2: 69–13. JFM 61.0789.01. MR 1556908. Zbl 0011.22501.
  • Huber, Alfred (1957). "On subharmonic functions and differential geometry in the large". Commentarii Mathematici Helvetici. 32 (1): 13–72. doi:10.1007/BF02564570. hdl:2027/mdp.39015095254580. MR 0094452. Zbl 0080.15001.
  • Li, Peter (2000). "Curvature and function theory on Riemannian manifolds". In Yau, S.-T. (ed.). Surveys in Differential Geometry. Vol. 7. Somerville, MA: International Press. pp. 375–432. doi:10.4310/SDG.2002.v7.n1.a13. ISBN 1-57146-069-1. MR 1919432. Zbl 1066.53084.
  • Shiohama, Katsuhiro; Shioya, Takashi; Tanaka, Minoru (2003). The geometry of total curvature on complete open surfaces. Cambridge Tracts in Mathematics. Vol. 159. Cambridge: Cambridge University Press. doi:10.1017/CBO9780511543159. ISBN 0-521-45054-3. MR 2028047. Zbl 1086.53056.

External links edit

  • Gauss–Bonnet theorem, in the Encyclopedia of Mathematics, including a brief account of Cohn-Vossen's inequality

April 11, 2024
cohn, vossen, inequality, differential, geometry, named, after, stefan, cohn, vossen, relates, integral, gaussian, curvature, compact, surface, euler, characteristic, akin, gauss, bonnet, theorem, compact, surface, divergent, path, within, riemannian, manifold. In differential geometry Cohn Vossen s inequality named after Stefan Cohn Vossen relates the integral of Gaussian curvature of a non compact surface to the Euler characteristic It is akin to the Gauss Bonnet theorem for a compact surface A divergent path within a Riemannian manifold is a smooth curve in the manifold that is not contained within any compact subset of the manifold A complete manifold is one in which every divergent path has infinite length with respect to the Riemannian metric on the manifold Cohn Vossen s inequality states that in every complete Riemannian 2 manifold S with finite total curvature and finite Euler characteristic we have 1 SKdA 2px S displaystyle iint S K dA leq 2 pi chi S where K is the Gaussian curvature dA is the element of area and x is the Euler characteristic Examples editIf S is a compact surface without boundary then the inequality is an equality by the usual Gauss Bonnet theorem for compact manifolds If S has a boundary then the Gauss Bonnet theorem gives SKdA 2px S Skgds displaystyle iint S K dA 2 pi chi S int partial S k g ds nbsp dd where kg displaystyle k g nbsp is the geodesic curvature of the boundary and its integral the total curvature which is necessarily positive for a boundary curve and the inequality is strict A similar result holds when the boundary of S is piecewise smooth If S is the plane R2 then the curvature of S is zero and x S 1 so the inequality is strict 0 lt 2p Notes and references edit Robert Osserman A Survey of Minimal Surfaces Courier Dover Publications 2002 page 86 Cohn Vossen Stefan 1935 Kurzeste Wege und Totalkrummung auf Flachen Compositio Mathematica 2 69 13 JFM 61 0789 01 MR 1556908 Zbl 0011 22501 Huber Alfred 1957 On subharmonic functions and differential geometry in the large Commentarii Mathematici Helvetici 32 1 13 72 doi 10 1007 BF02564570 hdl 2027 mdp 39015095254580 MR 0094452 Zbl 0080 15001 Li Peter 2000 Curvature and function theory on Riemannian manifolds In Yau S T ed Surveys in Differential Geometry Vol 7 Somerville MA International Press pp 375 432 doi 10 4310 SDG 2002 v7 n1 a13 ISBN 1 57146 069 1 MR 1919432 Zbl 1066 53084 Shiohama Katsuhiro Shioya Takashi Tanaka Minoru 2003 The geometry of total curvature on complete open surfaces Cambridge Tracts in Mathematics Vol 159 Cambridge Cambridge University Press doi 10 1017 CBO9780511543159 ISBN 0 521 45054 3 MR 2028047 Zbl 1086 53056 External links editGauss Bonnet theorem in the Encyclopedia of Mathematics including a brief account of Cohn Vossen s inequality Retrieved from https en wikipedia org w index php title Cohn Vossen 27s inequality amp oldid 1170308097, wikipedia, wiki, book, books, library,

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