In mathematics, in the field of algebraic geometry, the period mapping relates families of Kähler manifolds to families of Hodge structures.
See main article: Ehresmann's theorem.
Let be a holomorphic submersive morphism. For a point b of B, we denote the fiber of f over b by Xb. Fix a point 0 in B. Ehresmann's theorem guarantees that there is a small open neighborhood U around 0 in which f becomes a fiber bundle. That is, is diffeomorphic to . In particular, the composite map
Xb\hookrightarrowf-1(U)\congX0 x U\twoheadrightarrowX0
The diffeomorphism from Xb to X0 induces an isomorphism of cohomology groups
| k(X | |
| H | |
| b, |
Z)\cong
| k(X | |
| H | |
| b |
x U,Z)\cong
| k(X | |
| H | |
| 0 |
x U,Z)\cong
| k(X | |
| H | |
| 0, |
Z),
Assume that f is proper and that X0 is a Kähler variety. The Kähler condition is open, so after possibly shrinking U, Xb is compact and Kähler for all b in U. After shrinking U further we may assume that it is contractible. Then there is a well-defined isomorphism between the cohomology groups of X0 and Xb. These isomorphisms of cohomology groups will not in general preserve the Hodge structures of X0 and Xb because they are induced by diffeomorphisms, not biholomorphisms. Let denote the pth step of the Hodge filtration. The Hodge numbers of Xb are the same as those of X0,[1] so the number is independent of b. The period map is the map
l{P}:U\rarrF=
| F | |
| b1,k,\ldots,bk,k |
| k(X | |
| (H | |
| 0, |
C)),
b\mapsto(FpH
| k(X | |
| b, |
C))p.
Because Xb is a Kähler manifold, the Hodge filtration satisfies the Hodge–Riemann bilinear relations. These imply that
| k(X | |
| H | |
| b, |
C)=FpH
| k(X | |
| b, |
C) ⊕ \overline{Fk-p+1
| k(X | |
| H | |
| b, |
C)}.
l{D}
l{D}
Assume now not just that each Xb is Kähler, but that there is a Kähler class that varies holomorphically in b. In other words, assume there is a class ω in such that for every b, the restriction ωb of ω to Xb is a Kähler class. ωb determines a bilinear form Q on Hk(Xb, C) by the rule
Q(\xi,η)=\int
| n-k | |
| \omega | |
| b |
\wedge\xi\wedgeη.
style(-1)k(k-1)/2ip-qQ
The polarized local period domain and the polarized period mapping are still denoted
l{D}
l{P}
Focusing only on local period mappings ignores the information present in the topology of the base space B. The global period mappings are constructed so that this information is still available. The difficulty in constructing global period mappings comes from the monodromy of B: There is no longer a unique homotopy class of diffeomorphisms relating the fibers Xb and X0. Instead, distinct homotopy classes of paths in B induce possibly distinct homotopy classes of diffeomorphisms and therefore possibly distinct isomorphisms of cohomology groups. Consequently there is no longer a well-defined flag for each fiber. Instead, the flag is defined only up to the action of the fundamental group.
In the unpolarized case, define the monodromy group Γ to be the subgroup of GL(Hk(X0, Z)) consisting of all automorphisms induced by a homotopy class of curves in B as above. The flag variety is a quotient of a Lie group by a parabolic subgroup, and the monodromy group is an arithmetic subgroup of the Lie group. The global unpolarized period domain is the quotient of the local unpolarized period domain by the action of Γ (it is thus a collection of double cosets). In the polarized case, the elements of the monodromy group are required to also preserve the bilinear form Q, and the global polarized period domain is constructed as a quotient by Γ in the same way. In both cases, the period mapping takes a point of B to the class of the Hodge filtration on Xb.
Griffiths proved that the period map is holomorphic. His transversality theorem limits the range of the period map.
The Hodge filtration can be expressed in coordinates using period matrices. Choose a basis δ1, ..., δr for the torsion-free part of the kth integral homology group . Fix p and q with, and choose a basis ω1, ..., ωs for the harmonic forms of type . The period matrix of X0 with respect to these bases is the matrix
\Omega=
| (\int | |
| \deltai |
\omegaj)1.
The entries of the period matrix depend on the choice of basis and on the complex structure. The δs can be varied by a choice of a matrix Λ in, and the ωs can be varied by a choice of a matrix A in . A period matrix is equivalent to Ω if it can be written as AΩΛ for somechoice of A and Λ.
Consider the family of elliptic curves
y2=x(x-1)(x-λ)
H1,0 is one-dimensional because the curve is elliptic, and for all λ, it is spanned by the differential form . To find explicit representatives of the homology group of the curve, note that the curve can be represented as the graph of the multivalued function
y=\sqrt{x(x-1)(x-λ)}
\begin{pmatrix}\int\gamma\omega\ \int\delta\omega\end{pmatrix}.
The bilinear form Q is positive definite because locally, we can always write ω as f dz, hence
| \sqrt{-1}\int | |
| X0 |
\omega\wedge\bar\omega=
| \sqrt{-1}\int | |
| X0 |
|f|2dz\wedged\bar{z}>0.
\omega=A\gamma*+B\delta*.
| \sqrt{-1}\int | |
| X0 |
A\bar{B}\gamma*\wedge\bar{\delta}*+\bar{A}B\bar{\gamma}*\wedge\delta*=
| \int | |
| X0 |
\operatorname{Im}(2\bar{A}B\bar{\gamma}*\wedge\delta*)>0
\operatorname{Im}2\bar{A}B
After rescaling ω, we may assume that the period matrix equals for some complex number τ with strictly positive imaginary part. This removes the ambiguity coming from the action. The action of is then the usual action of the modular group on the upper half-plane. Consequently, the period domain is the Riemann sphere. This is the usual parameterization of an elliptic curve as a lattice.
xm+yn=1