An algebraic number field is a finite-dimensional extension of the rational numbers Q. Such a number field has a primitive element and it can be defined by the minimal polynomial of this primitive element. Another important way to define an algebraic number field is by a set of rational matrices which generate a number field.
We provide functions to create number fields defined by rational matrices or by rational polynomials.
FieldByMatricesNC(
matrices )
FieldByMatrices(
matrices )
Creates a field generated by the rational matrices matrices. In the faster NC version, the function assumes that the input generates a field and there are no checks on this performed.
FieldByMatrixBasisNC(
matrices )
FieldByMatrixBasis(
matrices )
Creates a field with basis matrices. The list matrices must consist of rational matrices which form a basis for a number field. In the faster NC version, the function assumes that the input is a matrix basis for a field and no checks are performed.
FieldByPolynomialNC(
polynomial )
FieldByPolynomial(
polynomial )
Creates a field defined by polynomial. The polynomial polynomial must be an irreducible rational polynomial. In the faster NC version, no checks on the input are performed.
We outline a number of functions for number fields.
PrimitiveElement(
F )
DefiningPolynomial(
F )
Computes a primitive element and a defining polynomial for the given number
field. The defining polynomial is the minimal polynomial of the primitive
element. Since F contains various primitive elements,
PrimitiveElement
tries to find a primitive element which has a
minimal polynomial with small coefficients. Via the global variable
PRIM_TEST the user can decide how many primitive elements will be
compared. The default value is 20.
IsPrimitiveElementOfNumberField(
F,
a )
Checks if the given element generates the field.
DegreeOverPrimeField(
F )
Returns the degree of F over the rationals.
EquationOrderBasis(
F )
MaximalOrderBasis(
F )
IsIntegerOfNumberField(
F,
k )
These functions return bases for the equation order or the maximal order of the number field F. Also, they allow to check if a given element is an integer in the given number field.
UnitGroup(
F )
determines the unit group of F.
Recall that the unit group of F is a finitely generated abelian
group. The function IsomorphismPcpGroup
from the Polycyclic
Polycyclic package gives an isomorphism to a pcp group which
can be used for various computations with the unit group.
IsUnitOfNumberField(
F,
k )
checks whether the element k is a unit in F.
ExponentsOfUnits(
F,
elms )
This function determines the exponent vectors of the elements in elms with respect to the generators of the unit group of F. If the unit group of F is not known, then the function computes this unit group also.
IsCyclotomicField(
F )
Check whether F is cyclotomic.
NormCosetsOfNumberField(
F,
norm )
Returns a description for the set of all elements of norm norm in F. These elements can be written as a finite union of cosets of the unit group of F. The function returns coset representatives for these cosets.
Suppose that a finite number of invertible elements of a number field are given. Then these elements generate a finitely generated abelian group. However, it is a non-trivial task to provide a presentation for this abelian group. The most useful representation for such groups is as pcp group.
PcpPresentationOfMultiplicativeSubgroup(
F,
elms )
IsomorphismPcpGroup(
F,
elms )
Determine a pcp presentation for the multiplicative group of
F \{0} generated by
elms and an isomorphism on this presentation.
Note, that the method IsomorphismPcpGroup
is defined in the
Polycyclic package Polycyclic. We refer to the manual of this
package for further background.
In the determination of the Pcp-presentation of a multiplicative
subgroup generated by elms the relations between the elements in
elms play an important role.
Let elms={e1,...,el} be a finite subset of a field F.
The relation lattice for elms is
|
RelationLattice(
F,
elms )
Determines a generating set for the relation lattice of the field elements elms.
RelationLatticeOfUnits(
F,
elms )
Determines a basis for the relation lattice of the units elms in
triangularized form. Note that this method is more efficient than
the method RelationLattice
.
IntersectionOfUnitSubgroups(
F,
gen1,
gen2 )
The lists gen1 and gen2 are supposed to generate two subgroups U1 and U2 of the unit group of F. This function determines the intersection of U1 with U2. The result is returned as a list of vectors generating the lattice { e ∈ Zn | g1e1 …gnen ∈ U2 } for gen1 = [g1, …, gn].
For efficiency reasons this function does not check the input and it may return wrong results if the input generators do not fulfil the requirements.
FactorsPolynomialAlgExt(
F,
pol )
embeds the rational polynomial pol into the polynomial ring over the
number field F, which has to be constructed by FieldByPolynomial
or AlgebraicExtension
, and returns the factorization of the embedded
polynomial. By default a denotes the primitive element of the field
one can obtain from PrimitiveElement(
F)
, that is, a root of the
defining polynomial of F.
FactorsPolynomialPari(
pol )
takes a polynomial pol defined over an algebraic extension of the Rationals and factors it using PARI/GP.
gap> x := Indeterminate( Rationals, "x" );; gap> pol := 2*x^7+2*x^5+8*x^4+8*x^2; 2*x^7+2*x^5+8*x^4+8*x^2 gap> L := FieldByPolynomial( x^3-4 ); <algebraic extension over the Rationals of degree 3> gap> y := Indeterminate( L, "y" );; gap> FactorsPolynomialAlgExt( L, pol ); [ !2*y, y, y+(a), y^2+!1, y^2+((-1*a))*y+(a^2) ] gap> FactorsPolynomialPari( last[5] ); [ y^2+((-1*a))*y+(a^2) ] gap>
ExampleMatField(
l )
This function returns some examples of fields generated by matrices. There are 9 such example fields provided and they can be obtained by assigning the input l to an integer between 1 and 9. Some of the properties of the examples are summarized in the following table.
degree over Q number of generators dim. of generators ExampleMatField(1) 4 4 4 ExampleMatField(2) 4 4 4 ExampleMatField(3) 4 4 4 ExampleMatField(4) 4 13 4 ExampleMatField(5) 4 13 4 ExampleMatField(6) 4 7 4 ExampleMatField(7) 4 18 4 ExampleMatField(8) 4 13 4 ExampleMatField(9) 4 7 4
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Alnuth manual