Difference between revisions of "Variation of Hodge structure"

A variation of Hodge structure of weight $ w $ on a complex manifold $ {\mathcal S} $ is a couple $ {\mathcal V} =( {\mathcal V} _ {\mathbf Z } , {\mathcal F} ^ {\bullet } ) $ where $ {\mathcal V} _ {\mathbf Z } $ is a locally constant sheaf of finitely-generated Abelian groups on $ {\mathcal S} $, and $ {\mathcal F} ^ {\bullet } $ is a finite decreasing filtration of $ V= {\mathcal V} _ {\mathbf Z } \otimes _ {\mathbf Z } {\mathcal O} _ {\mathcal S} $ by holomorphic subbundles, subject to the following conditions: i) the flat connection $ \nabla $ on $ V $ defined by $ \nabla ( v\otimes f )= v\otimes df $, for $ v $, $ f $ local sections of $ {\mathcal V} _ {\mathbf Z } $ and $ {\mathcal O} _ {\mathcal S} $, respectively, satisfies $ \nabla ( {\mathcal F} ^ {p} )\subset {\mathcal F} ^ {p- 1 } \otimes \Omega _ {\mathcal S} ^ {1} $( Griffiths' transversality); ii) for each $ s \in {\mathcal S} $, the pair $ ( {\mathcal V} _ {\mathbf Z ,s } , {\mathcal F} ^ {\bullet } ( s)) $ is a Hodge structure of weight $ w $.

A polarization of a variation of Hodge structure $ ( {\mathcal V} _ {\mathbf Z } , {\mathcal F} ^ {\bullet } ) $ is a flat bilinear form $ {\mathcal V} _ {\mathbf Z } \otimes {\mathcal V} _ {\mathbf Z } \rightarrow \mathbf Z _ {\mathcal S} $ which induces a polarization of the Hodge structure $ {\mathcal V} _ {\mathbf Z ,s } $ for each $ s \in {\mathcal S} $. Similar notions exist for $ \mathbf Z $ replaced by $ \mathbf Q $ or $ \mathbf R $, [a2]. If $ f: X \rightarrow S $ is a proper smooth morphism of algebraic varieties over $ \mathbf C $, then $ R ^ {m} f _ {*} \mathbf Z _ {X} $ is the underlying local system of a polarizable variation of Hodge structure on $ {\mathcal S} $. By a result of A. Borel, for a polarized variation of Hodge structure on a complex manifold $ S $ of the form $ \overline{S}\; \setminus D $, where $ \overline{S}\; $ is compact and $ D\subset \overline{S}\; $ is a divisor with normal crossings, the monodromy around each local component of $ D $ is quasi-unipotent [a3] (monodromy theorem). A polarized variation of Hodge structure over $ S $ gives rise to a holomorphic period mapping from $ S $ to a classifying space of Hodge structures (see Period mapping).

If $ {\mathcal S} = \overline{S}\; \setminus D $ with $ \overline{S}\; $ a compact Kähler manifold and $ D $ a divisor with normal crossings on $ \overline{S}\; $, then for a polarized variation of Hodge structure $ ( {\mathcal V} _ {\mathbf Z } , {\mathcal F} ^ {\bullet } ) $ on $ S $, the sheaf $ {\mathcal V} _ {\mathbf Z } $ has a minimal extension to a perverse sheaf $ IC( {\mathcal V} _ {\mathbf Z } ) $ on $ \overline{S}\; $ and $ IH ^ {*} ( \overline{S}\; , IC( {\mathcal V} _ {\mathbf Z } )) $ carries a pure Hodge structure [a4]–[a6]. In fact, $ IC( {\mathcal V} _ {\mathbf Z } ) $ is part of a polarized Hodge module [a7]. Generalizations are the notions of variation of mixed Hodge structure [a8], [a9] and mixed Hodge module [a10].

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