Difference between revisions of "Bianchi surface"
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| − | A surface of negative Gaussian curvature | + | {{TEX|done}} |
| + | A surface of negative Gaussian curvature $K$ which can be expressed in asymptotic parameters $(u,v)$ as | ||
| − | + | $$K=-\frac{1}{[U(u)+V(v)]^2},$$ | |
| − | where | + | where $U(u)$ and $V(v)$ are arbitrary functions; thus, Bianchi surfaces can be characterized by the fact that the function $(-K)^{-1/2}$ is diagonal with respect to its asymptotic net, i.e. |
| − | + | $$\frac{\partial^2(-K)^{-1/2}}{\partial u\partial v}=0.$$ | |
| − | For instance, a ruled Bianchi surface is a [[Conoid|conoid]] — a surface attached to the [[Peterson surface|Peterson surface]]. If a Bianchi surface is given, it is possible to determine the classes of surfaces which can be obtained by a [[Deformation over a principal base|deformation over a principal base]] and to classify them. Thus, if the principal base contains two families of geodesic lines, the functions | + | For instance, a ruled Bianchi surface is a [[Conoid|conoid]] — a surface attached to the [[Peterson surface|Peterson surface]]. If a Bianchi surface is given, it is possible to determine the classes of surfaces which can be obtained by a [[Deformation over a principal base|deformation over a principal base]] and to classify them. Thus, if the principal base contains two families of geodesic lines, the functions $U$ and $V$ are constant and the bent surface is a [[Voss surface|Voss surface]] (the class $B_0$). |
| − | The class | + | The class $B_1$ is characterized by the fact that only one family of lines of the principal base are geodesics (one of the functions $U,V$ is constant); conoids may serve as an example. The class $B_2$ corresponds to functions $U,V$ which both depend non-trivially on their arguments. See also [[Bianchi congruence|Bianchi congruence]]. |
Latest revision as of 14:19, 29 April 2014
A surface of negative Gaussian curvature $K$ which can be expressed in asymptotic parameters $(u,v)$ as
$$K=-\frac{1}{[U(u)+V(v)]^2},$$
where $U(u)$ and $V(v)$ are arbitrary functions; thus, Bianchi surfaces can be characterized by the fact that the function $(-K)^{-1/2}$ is diagonal with respect to its asymptotic net, i.e.
$$\frac{\partial^2(-K)^{-1/2}}{\partial u\partial v}=0.$$
For instance, a ruled Bianchi surface is a conoid — a surface attached to the Peterson surface. If a Bianchi surface is given, it is possible to determine the classes of surfaces which can be obtained by a deformation over a principal base and to classify them. Thus, if the principal base contains two families of geodesic lines, the functions $U$ and $V$ are constant and the bent surface is a Voss surface (the class $B_0$).
The class $B_1$ is characterized by the fact that only one family of lines of the principal base are geodesics (one of the functions $U,V$ is constant); conoids may serve as an example. The class $B_2$ corresponds to functions $U,V$ which both depend non-trivially on their arguments. See also Bianchi congruence.
Comments
The notion of a "deformation over a principal base" is not very common in Western literature, and this type of deformation has no standard name even. It can best be characterized as a deformation preserving a conjugate net.
References
| [a1] | L. Bianchi, "Lezioni di geometria differenziale" , 2 , Zanichelli , Bologna (1927) pp. Chapt. 1 |
| [a2] | S.P. Finikov, "Theorie der Kongruenzen" , Akademie Verlag (1959) (Translated from Russian) |
Bianchi surface. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Bianchi_surface&oldid=11564