Hypersurface
A generalization of the concept of an ordinary surface in three-dimensional space to the case of an 
-dimensional space. The dimension of a hypersurface is one less than that of its ambient space.
If 
and 
are differentiable manifolds, 
, and if an immersion 
has been defined, then 
is a hypersurface in 
. Here 
is a differentiable mapping whose differential 
at any point 
is an injective mapping of the tangent space 
to 
at 
into the tangent space 
to 
at 
.
Comments
References
| [a1] | M. Spivak, "A comprehensive introduction to differential geometry" , 1979 , Publish or Perish (1975) pp. 1–5 |
An algebraic hypersurface is a subvariety of an algebraic variety that is locally defined by one equation. An algebraic hypersurface in the affine space 
over a field 
is globally defined by one equation
 |
An algebraic hypersurface 
in a projective space 
is defined by an equation
 |
where 
is a homogeneous form in 
variables. The degree 
of this form is said to be the degree (order) of the hypersurface. A closed subscheme 
of a scheme 
is said to be a hypersurface if the corresponding sheaf of ideals 
is a sheaf of principal ideals. For a connected non-singular algebraic variety this condition means that the codimension of 
in 
is one. For each non-singular algebraic hypersurface 
of order 
(often denoted by 
) the following holds:
a) the canonical class 
is equal to 
where 
is the class of a hyperplane section of 
;
b) the cohomology groups 
for 
, and
 |
c) if 
, the fundamental group (algebraic or topological if 
) 
;
d) if 
, the Picard group 
and is generated by the class of a hyperplane section.
I.V. Dolgachev
Comments
The cohomology ring of a smooth complex projective hypersurface can be expressed completely in terms of rational differential forms on the ambient projective space, [a1]. In most cases, the period mapping for these hypersurfaces has been shown to be of degree one [a2].
References
| [a1] | J. Carlson, P. Griffiths, "Infinitesimal variations of Hodge structure and the global Torelli problem" A. Beauville (ed.) , Algebraic geometry (Angers, 1979) , Sijthoff & Noordhoff (1980) pp. 51–76 |
| [a2] | R. Donagi, "Generic Torelli for projective hypersurfaces" Compos. Math. , 50 (1983) pp. 325–353 |
| [a3] | R. Hartshorne, "Algebraic geometry" , Springer (1977) pp. 13; 170; 316; 381 |
An analytic hypersurface is a set 
in a complex Euclidean space 
that, in a neighbourhood of each of its points 
, is defined by an equation 
, where the function 
is continuous with respect to the parameter 
, 
, and, for each fixed 
, is holomorphic in 
in a neighbourhood 
which is independent of 
; moreover, 
for all 
. In other words, an analytic hypersurface is a set in 
that is locally the union of a continuous one-parameter family of complex-analytic surfaces of complex codimension one. For instance, if a function 
is holomorphic in a domain 
and 
in 
, then the sets 
, 
, etc., are analytic hypersurfaces.
A twice-differentiable hypersurface 
in 
is an analytic hypersurface if and only if its Levi form vanishes identically on 
or if 
is locally pseudo-convex on both sides.
E.M. Chirka
Comments
Sometimes the phrase "analytic hypersurface" is also used for an analytic set of complex codimension 1, analogously to 3) above, cf. [a1]. An analytic hypersurface as in 4) is also called a foliation by analytic varieties of codimension 1. The result concerning a twice-differentiable 
, mentioned above, can be found in [a2].
References
| [a1] | H. Grauert, R. Remmert, "Theory of Stein spaces" , Springer (1977) (Translated from German) |
| [a2] | V.S. Vladimirov, "Methods of the theory of functions of several complex variables" , M.I.T. (1966) (Translated from Russian) |
| [a3] | L. Kaup, B. Kaup, "Holomorphic functions of several variables" , de Gruyter (1983) (Translated from German) |
Hypersurface. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Hypersurface&oldid=14567