Difference between revisions of "Asymptotic line"
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| + | A curve $ \Gamma $ | ||
| + | on a regular surface $ F $ | ||
| + | such that the normal curvature along $ \Gamma $ | ||
| + | is zero. An asymptotic line is given by the differential equation: | ||
| + | |||
| + | $$ | ||
| + | \textrm{ II } = L du ^ {2} +2M du dv + N dv ^ {2} = 0 , | ||
| + | $$ | ||
where II is the second fundamental form of the surface. | where II is the second fundamental form of the surface. | ||
| − | The osculating plane of an asymptotic line | + | The osculating plane of an asymptotic line $ \Gamma $, |
| + | if it exists, coincides with the tangent plane to $ F $( | ||
| + | at the points of $ \Gamma $), | ||
| + | and the square of the torsion of an asymptotic line is equal to the modulus of the Gaussian curvature $ K $ | ||
| + | of the surface $ F $( | ||
| + | the Beltrami–Enneper theorem). A straight line $ l \in F $( | ||
| + | e.g. a generating line of a ruled surface) is always an asymptotic line. If $ \Gamma $ | ||
| + | is a parabolic curve (e.g. a circle on a standard torus separating the domains of Gaussian curvatures of different signs), it is an asymptotic line. | ||
| − | A unique asymptotic line, which coincides with the rectilinear generator, passes through each point of a parabolic domain (where | + | A unique asymptotic line, which coincides with the rectilinear generator, passes through each point of a parabolic domain (where $ K = 0 $, |
| + | but II $ \neq 0 $). | ||
| + | Through each point of a hyperbolic domain (where $ K<0 $) | ||
| + | there pass exactly two asymptotic lines, forming the so-called [[Asymptotic net|asymptotic net]], which plays an important role in the study of the spatial form of a surface of negative curvature (cf. [[Negative curvature, surface of|Negative curvature, surface of]]). For instance, on a complete surface this net is homeomorphic to the Cartesian net on the plane if | ||
| − | + | $$ | |
| + | \mathop{\rm grad} \left | | ||
| + | \frac{1} {\sqrt | ||
| + | {-K}} \right | \leq q,\ \ | ||
| + | q = \textrm{ const } . | ||
| + | $$ | ||
| − | Asymptotic nets on surfaces of constant negative curvature are Chebyshev nets (cf. [[Chebyshev net|Chebyshev net]]), and the surface area of a quadrangle formed by asymptotic lines is proportional to the excess of the sum of its interior angles | + | Asymptotic nets on surfaces of constant negative curvature are Chebyshev nets (cf. [[Chebyshev net|Chebyshev net]]), and the surface area of a quadrangle formed by asymptotic lines is proportional to the excess of the sum of its interior angles $ \alpha _ {i} $ |
| + | over $ 2 \pi $: | ||
| − | + | $$ | |
| + | | K | S = 2 \pi - \alpha _ {1} - \alpha _ {2} - \alpha _ {3} - | ||
| + | \alpha _ {4} $$ | ||
(Hazzidakis' formula). | (Hazzidakis' formula). | ||
| − | Under a projective transformation | + | Under a projective transformation $ \pi $ |
| + | of the space, the asymptotic lines of a surface $ F $ | ||
| + | become the asymptotic lines of the transformed surface $ \pi (F) $. | ||
Asymptotic lines on surfaces in a three-dimensional Riemannian space are defined in a similar manner. Various generalizations of the concept of an asymptotic line on manifolds imbedded in a multi-dimensional space are known; the most frequently-used one involves the concept of the second fundamental form, which is associated with a given normal vector. | Asymptotic lines on surfaces in a three-dimensional Riemannian space are defined in a similar manner. Various generalizations of the concept of an asymptotic line on manifolds imbedded in a multi-dimensional space are known; the most frequently-used one involves the concept of the second fundamental form, which is associated with a given normal vector. | ||
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====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> A.V. Pogorelov, "Differential geometry" , Noordhoff (1959) (Translated from Russian)</TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> P.K. Rashevskii, "A course of differential geometry" , Moscow (1956) (In Russian)</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> A.V. Pogorelov, "Differential geometry" , Noordhoff (1959) (Translated from Russian)</TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> P.K. Rashevskii, "A course of differential geometry" , Moscow (1956) (In Russian)</TD></TR></table> | ||
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====Comments==== | ====Comments==== | ||
Latest revision as of 21:17, 5 April 2020
A curve $ \Gamma $
on a regular surface $ F $
such that the normal curvature along $ \Gamma $
is zero. An asymptotic line is given by the differential equation:
$$ \textrm{ II } = L du ^ {2} +2M du dv + N dv ^ {2} = 0 , $$
where II is the second fundamental form of the surface.
The osculating plane of an asymptotic line $ \Gamma $, if it exists, coincides with the tangent plane to $ F $( at the points of $ \Gamma $), and the square of the torsion of an asymptotic line is equal to the modulus of the Gaussian curvature $ K $ of the surface $ F $( the Beltrami–Enneper theorem). A straight line $ l \in F $( e.g. a generating line of a ruled surface) is always an asymptotic line. If $ \Gamma $ is a parabolic curve (e.g. a circle on a standard torus separating the domains of Gaussian curvatures of different signs), it is an asymptotic line.
A unique asymptotic line, which coincides with the rectilinear generator, passes through each point of a parabolic domain (where $ K = 0 $, but II $ \neq 0 $). Through each point of a hyperbolic domain (where $ K<0 $) there pass exactly two asymptotic lines, forming the so-called asymptotic net, which plays an important role in the study of the spatial form of a surface of negative curvature (cf. Negative curvature, surface of). For instance, on a complete surface this net is homeomorphic to the Cartesian net on the plane if
$$ \mathop{\rm grad} \left | \frac{1} {\sqrt {-K}} \right | \leq q,\ \ q = \textrm{ const } . $$
Asymptotic nets on surfaces of constant negative curvature are Chebyshev nets (cf. Chebyshev net), and the surface area of a quadrangle formed by asymptotic lines is proportional to the excess of the sum of its interior angles $ \alpha _ {i} $ over $ 2 \pi $:
$$ | K | S = 2 \pi - \alpha _ {1} - \alpha _ {2} - \alpha _ {3} - \alpha _ {4} $$
(Hazzidakis' formula).
Under a projective transformation $ \pi $ of the space, the asymptotic lines of a surface $ F $ become the asymptotic lines of the transformed surface $ \pi (F) $.
Asymptotic lines on surfaces in a three-dimensional Riemannian space are defined in a similar manner. Various generalizations of the concept of an asymptotic line on manifolds imbedded in a multi-dimensional space are known; the most frequently-used one involves the concept of the second fundamental form, which is associated with a given normal vector.
References
| [1] | A.V. Pogorelov, "Differential geometry" , Noordhoff (1959) (Translated from Russian) |
| [2] | P.K. Rashevskii, "A course of differential geometry" , Moscow (1956) (In Russian) |
Comments
Hazzidakis' formula can be found in [a1] and [a2], p. 204.
References
| [a1] | J.N. Hazzidakis, "Uber einige Eigenschaften der Flächen mit konstanten Krümmungsmasz" Crelle's J. Math. , 88 (1880) pp. 68–73 |
| [a2] | D.J. Struik, "Lectures on classical differential geometry" , Addison-Wesley (1950) |
| [a3] | C.C. Hsiung, "A first course in differential geometry" , Wiley (1981) pp. Chapt. 3, Sect. 4 |
| [a4] | M. Spivak, "A comprehensive introduction to differential geometry" , 3 , Publish or Perish (1975) pp. 1–5 |
| [a5] | N.J. Hicks, "Notes on differential geometry" , v. Nostrand (1965) |
| [a6] | W. Blaschke, K. Leichtweiss, "Elementare Differentialgeometrie" , Springer (1973) |
Asymptotic line. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Asymptotic_line&oldid=12030