isLinearType -- Determine whether module has linear type

Synopsis

Usage:

isLinearType M

isLinearType(M,f)
Inputs:
- M, a module, or an ideal
- f, a ring element, any non-zero divisor modulo the ideal or module. Optional
Optional inputs:
- BasisElementLimit => ..., default value infinity, Bound the number of Groebner basis elements to compute in the saturation step
- DegreeLimit => ..., default value {}, Bound the degrees considered in the saturation step. Defaults to infinity
- MinimalGenerators => ..., default value true, Whether the saturation step returns minimal generators
- PairLimit => ..., default value infinity, Bound the number of s-pairs considered in the saturation step
- Strategy => ..., default value null, Choose a strategy for the saturation step
Outputs:
- a Boolean value, true if M is of linear type, false otherwise

Description

A module or ideal $M$ is said to be ``of linear type'' if the natural map from the symmetric algebra of $M$ to the Rees algebra of $M$ is an isomorphism. It is known, for example, that any complete intersection ideal is of linear type.

This routine computes the reesIdeal of M. Giving the element f computes the reesIdeal in a different manner, which is sometimes faster, sometimes slower.

i1 : S = QQ[x_0..x_4]

o1 = S

o1 : PolynomialRing

i2 : i = monomialCurveIdeal(S,{2,3,5,6})

                          2                       3      2     2      2     2    2     2              3    2
o2 = ideal (x x  - x x , x  - x x , x x  - x x , x  - x x , x x  - x x , x x  - x x , x x  - x x x , x  - x x )
             2 3    1 4   2    0 4   1 2    0 3   3    2 4   1 3    0 4   0 3    1 4   1 3    0 2 4   1    0 4

o2 : Ideal of S

i3 : isLinearType i

o3 = false

i4 : isLinearType(i, i_0)

o4 = false

i5 : I = reesIdeal i

                                                     2                                         2                   2           
o5 = ideal (x w  - x w  + x w , x w  - x w  + x w , x w  + x w  - x w , x x w  + x w  - x w , x w  + x w  - x w , x w  + x w  -
             2 0    3 1    4 2   0 0    1 1    2 2   4 2    1 3    3 4   0 4 2    1 5    3 6   3 2    0 3    2 4   1 2    0 5  
     ----------------------------------------------------------------------------------------------------------------------------
                                                                          2      2                                         2    
     x w , x x w  - x x w  - x w  + x w , x x w  - x x w  - x w  + x w , x w  - x w  - x w  + x w , x x w  - x w  + x w , x w  -
      2 6   1 4 1    2 4 2    1 4    3 5   0 4 1    1 3 2    0 4    2 5   3 0    4 1    2 3    4 4   1 3 0    2 4    4 5   1 0  
     ----------------------------------------------------------------------------------------------------------------------------
                                2    2                                       2                         2
     x x w  - x w  + x w , x x w  - w  - x w w  + w w , x x w w  - x w w  + w  - w w , x x w w  - x x w  + w w  - w w )
      1 3 2    0 4    4 6   1 4 2    5    4 1 6    4 6   3 4 0 2    4 1 4    4    3 5   1 4 0 2    3 4 2    4 5    3 6

o5 : Ideal of S[w ..w ]
                 0   6

i6 : select(I_*, f -> first degree f > 1)

           2    2                                       2                         2
o6 = {x x w  - w  - x w w  + w w , x x w w  - x w w  + w  - w w , x x w w  - x x w  + w w  - w w }
       1 4 2    5    4 1 6    4 6   3 4 0 2    4 1 4    4    3 5   1 4 0 2    3 4 2    4 5    3 6

o6 : List

i7 : S = ZZ/101[x,y,z]

o7 = S

o7 : PolynomialRing

i8 : for p from 1 to 5 do print isLinearType (ideal vars S)^p
true
false
false
false
false

Ways to use `isLinearType` :

"isLinearType(Ideal)"
"isLinearType(Ideal,RingElement)"
"isLinearType(Module)"
"isLinearType(Module,RingElement)"

For the programmer

The object isLinearType is a method function with options.

isLinearType -- Determine whether module has linear type

Synopsis

Description

See also

Ways to use isLinearType :

For the programmer

Ways to use `isLinearType` :