Intersections of modules can taken. Several other functions are also available.
Return the intersection of the modules M1 and M2.
The module dual to M.
The elementary divisors (ideals) of the torsion part of the quotient R-module M/N: For N subseteq M we get T(M/N) isomorphic to oplus_(i=1)^n R/(frac A_i) The (frac A_i) are unique if we require R subseteq (frac A_1) subseteq ... subseteq (frac A_n). The (frac A_i) are called the elementary divisors (or elementary ideals) of M/N. This corresponds to the Smith normal form for integral matrices.
The Steinitz class of M.
The Steinitz (almost--free) form of M.
> P<x> := PolynomialRing(Rationals());
> P<y> := PolynomialRing(P);
> F<c> := FunctionField(y^3 - x^3*y^2 + y - x^7);
> M := MaximalOrderFinite(F);
> Vs := RSpace(M, 2);
> s := [Vs | [1, Random(M, 3)], [Random(M, 3), 3]];
> Mods := Module(s);
> qMods := quo<Mods | Mods!s[2]>;
> Basis(Mods);
[
([ 1, 0, 0 ] [ 2*x^2 - 3*x + 1/2, -2/3*x^2 - x + 1/3, 2/3*x^2 - 2*x + 1/2
]),
([ -x^2 + x + 2/3, -1/3*x^2 - 1, -3/2*x^2 - 2/3*x + 1 ] [ 3, 0, 0 ])
]
> Basis(qMods);
[
([ 1, 0, 0 ] [ 2*x^2 - 3*x + 1/2, -2/3*x^2 - x + 1/3, 2/3*x^2 - 2*x + 1/2
]),
([ -x^2 + x + 2/3, -1/3*x^2 - 1, -3/2*x^2 - 2/3*x + 1 ] [ 3, 0, 0 ])
]
> PseudoBasis(Mods) eq PseudoBasis(qMods);
> Vs := RModule(M, 2);
> s := [Vs | [Random(M, 3), Random(M, 3)], [2, 3]];
> Mods := Module(s);
> sMods := sub<Mods | Mods!s[1]>;
> Mods meet sMods;
Module over Maximal Equation Order of F over Univariate Polynomial Ring in x
over Rational Field
Ideal of M
Generator:
(x + 1)*c^2 + (-3/2*x^2 - 3/2*x)*c + 1/2*x^2 + 2/3*x + 1/2
> ElementaryDivisors(Mods, sMods);
[ Ideal of M
Basis:
[1 0 0]
[0 1 0]
[0 0 1], Ideal of M
Generator:
0 ]
> Dual(Mods);
Module over Maximal Equation Order of F over Univariate Polynomial Ring in x
over Rational Field
Fractional ideal of M
Generator:
(-3*x^4 + 21*x^3 + 20*x^2 + 80*x - 387)/(x^17 - 24*x^16 + 192*x^15 - 510*x^14 -
94/3*x^13 + 304/3*x^12 + 902/3*x^11 - 3109/3*x^10 - 389/9*x^9 + 664/9*x^8 +
1094/3*x^7 - 1540/3*x^6 - 101/9*x^5 + 128/3*x^4 + 2000/27*x^3 - 4361/9*x^2 -
427*x + 2056)*c^2 + (-3*x^9 + 48*x^8 - 189*x^7 - 24*x^6 + 3*x^5 - 48*x^4 +
195*x^3 - 3*x^2 - x + 24)/(x^17 - 24*x^16 + 192*x^15 - 510*x^14 - 94/3*x^13
+ 304/3*x^12 + 902/3*x^11 - 3109/3*x^10 - 389/9*x^9 + 664/9*x^8 + 1094/3*x^7
- 1540/3*x^6 - 101/9*x^5 + 128/3*x^4 + 2000/27*x^3 - 4361/9*x^2 - 427*x +
2056)*c + (3*x^12 - 48*x^11 + 192*x^10 + 3*x^9 - 20*x^8 - 56*x^7 + 192*x^6 +
3*x^5 - 5*x^4 - 8*x^3 + 272/3*x^2 + 128*x - 771)/(x^17 - 24*x^16 + 192*x^15
- 510*x^14 - 94/3*x^13 + 304/3*x^12 + 902/3*x^11 - 3109/3*x^10 - 389/9*x^9 +
664/9*x^8 + 1094/3*x^7 - 1540/3*x^6 - 101/9*x^5 + 128/3*x^4 + 2000/27*x^3 -
4361/9*x^2 - 427*x + 2056) car Ideal of M
Generator:
1/3
> Dual(sMods);
Module over Maximal Equation Order of F over Univariate Polynomial Ring in x
over Rational Field
Fractional ideal of M
Generator:
(3/2*x^6 + 3*x^5 - 3/4*x^4 - 4*x^3 - 25/12*x^2 - 5/6*x - 1/2)/(x^17 + 3*x^16 +
21/4*x^15 + 27/4*x^14 + 1/24*x^13 - 247/24*x^12 - 173/24*x^11 + 61/24*x^10 +
305/72*x^9 + 17/72*x^8 - 4*x^7 - 53/12*x^6 - 1/8*x^5 + 23/6*x^4 +
377/108*x^3 + 23/18*x^2 + 1/3*x + 1/8)*c^2 + (-5/2*x^9 - 5*x^8 - 1/4*x^7 +
9/2*x^6 + 13/4*x^5 + 5/4*x^4 - 3/4*x^3 - 7/4*x^2 - 3/4*x)/(x^17 + 3*x^16 +
21/4*x^15 + 27/4*x^14 + 1/24*x^13 - 247/24*x^12 - 173/24*x^11 + 61/24*x^10 +
305/72*x^9 + 17/72*x^8 - 4*x^7 - 53/12*x^6 - 1/8*x^5 + 23/6*x^4 +
377/108*x^3 + 23/18*x^2 + 1/3*x + 1/8)*c + (x^12 + 2*x^11 - 1/2*x^10 -
7/2*x^9 - 8/3*x^8 - 5/12*x^7 + 11/4*x^6 + 19/4*x^5 - 1/4*x^4 - 25/6*x^3 -
67/36*x^2 - 1/3*x - 1/4)/(x^17 + 3*x^16 + 21/4*x^15 + 27/4*x^14 + 1/24*x^13
- 247/24*x^12 - 173/24*x^11 + 61/24*x^10 + 305/72*x^9 + 17/72*x^8 - 4*x^7 -
53/12*x^6 - 1/8*x^5 + 23/6*x^4 + 377/108*x^3 + 23/18*x^2 + 1/3*x + 1/8)
> SteinitzClass(Mods) eq SteinitzClass(sMods);
false
> SteinitzForm(Mods);
Module over Maximal Equation Order of F over Univariate Polynomial Ring in x
over Rational Field
Ideal of M
Generator:
3 car Ideal of M
Generator:
1
> SteinitzForm(sMods);
Module over Maximal Equation Order of F over Univariate Polynomial Ring in x
over Rational Field
Ideal of M
Generator:
1