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D.4.19.4 regMonCurve
Procedure from library mregular.lib (see mregular_lib).
- Usage:
- regMonCurve (a0,...,an) ; ai integers with a0=0 < a1 < ... < an=:d
- Return:
- an integer, the Castelnuovo-Mumford regularity of the projective
monomial curve C in Pn(K) parametrically defined by
x(0) = t^d , x(1) = s^(a1)t^(d-a1) , ..... , x(n) = s^d
where K is the field of complex numbers.
(returns -1 if a0=0 < a1 < ... < an is not satisfied)
- Assume:
- a0=0 < a1 < ... < an are integers.
- Notes:
- 1. The defining ideal of the curve C, I in S=K[x(0),...,x(n)], is
determined by elimination.
2. The procedure regIdeal has been improved in this case since one
knows beforehand that the monomial ideal J=lead(std(I)) is of
nested type if the monomial ordering is dp, and that
reg(C)=reg(J) (see preprint 'Saturation and Castelnuovo-Mumford
regularity' by Bermejo-Gimenez, 2004).
3. If printlevel > 0 (default = 0) additional info is displayed:
- It says whether C is arithmetically Cohen-Macaulay or not.
- If C is not arith. Cohen-Macaulay, end(H^1(S/I)) is computed
and an upper bound for the a-invariant of S/I is given.
- It also determines one step of the minimal graded free
resolution (m.g.f.r.) of I where the regularity is attained
and gives the value of the regularity of the Hilbert function
of S/I when reg(I) is attained at the last step of a m.g.f.r.
Example:
| LIB "mregular.lib";
// The 1st example is the twisted cubic:
regMonCurve(0,1,2,3);
==> 2
// The 2nd. example is the non arithm. Cohen-Macaulay monomial curve in P4
// parametrized by: x(0)-s6,x(1)-s5t,x(2)-s3t3,x(3)-st5,x(4)-t6:
regMonCurve(0,1,3,5,6);
==> 3
// Additional information is displayed if you change printlevel (=1);
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