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Castelnuovo–Mumford regularity

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In algebraic geometry, the Castelnuovo–Mumford regularity of a coherent sheaf F over projective space P n {\displaystyle \mathbf {P} ^{n}} is the smallest integer r such that it is r-regular, meaning that

H i ( P n , F ( r i ) ) = 0 {\displaystyle H^{i}(\mathbf {P} ^{n},F(r-i))=0}

whenever i > 0 {\displaystyle i>0} . The regularity of a subscheme is defined to be the regularity of its sheaf of ideals. The regularity controls when the Hilbert function of the sheaf becomes a polynomial; more precisely dim H 0 ( P n , F ( m ) ) {\displaystyle H^{0}(\mathbf {P} ^{n},F(m))} is a polynomial in m when m is at least the regularity. The concept of r-regularity was introduced by David Mumford (1966, lecture 14), who attributed the following results to Guido Castelnuovo (1893):

  • An r-regular sheaf is s-regular for any s r {\displaystyle s\geq r} .
  • If a coherent sheaf is r-regular then F ( r ) {\displaystyle F(r)} is generated by its global sections.

Graded modules

A related idea exists in commutative algebra. Suppose R = k [ x 0 , , x n ] {\displaystyle R=k} is a polynomial ring over a field k and M is a finitely generated graded R-module. Suppose M has a minimal graded free resolution

F j F 0 M 0 {\displaystyle \cdots \rightarrow F_{j}\rightarrow \cdots \rightarrow F_{0}\rightarrow M\rightarrow 0}

and let b j {\displaystyle b_{j}} be the maximum of the degrees of the generators of F j {\displaystyle F_{j}} . If r is an integer such that b j j r {\displaystyle b_{j}-j\leq r} for all j, then M is said to be r-regular. The regularity of M is the smallest such r.

These two notions of regularity coincide when F is a coherent sheaf such that Ass ( F ) {\displaystyle \operatorname {Ass} (F)} contains no closed points. Then the graded module

M = d Z H 0 ( P n , F ( d ) ) {\displaystyle M=\bigoplus _{d\in \mathbb {Z} }H^{0}(\mathbf {P} ^{n},F(d))}

is finitely generated and has the same regularity as F.

See also

References

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