Groups defined by polycyclic presentations are called PcpGroups in GAP. We refer to the Polycyclic manual Polycyclic for further background.
Suppose that a collection X of matrices of GL(d,R) is given, where the ring R is either Q,Z or a finite field. Let G= < X >. If the group G is polycyclic, then the following functions determine a PcpGroup isomorphic to G.
PcpGroupByMatGroup(
G )
G is a subgroup of GL(d,R) where R=Q,Z or Fq. If G is polycyclic, then this function determines a PcpGroup isomorphic to G. If G is not polycyclic, then this function returns 'fail'.
IsomorphismPcpGroup(
G )
G is a subgroup of GL(d,R) where R=Q,Z or Fq. If G is polycyclic, then this function determines an isomorphism onto a PcpGroup. If G is not polycyclic, then this function returns 'fail'.
Note that the method IsomorphismPcpGroup
,
installed in this package, cannot be
applied directly to a group given by the function AlmostCrystallographicGroup
.
Please use POL_AlmostCrystallographicGroup
(with the same
parameters as AlmostCrystallographicGroup
) instead.
Image(
map )
ImageElm(
map,
elm )
ImagesSet(
map,
elms )
PreImage(
map,
pcpelm )
Here map is an isomorphism from a polycyclic matrix group G
onto a PcpGroup H calculated
by IsomorphismPcpGroup(
G)
.
These functions can be used to compute with such an isomorphism.
If the input elm is an element of G, then the function ImageElm
can be used to compute the image of elm under map.
If elm is not contained in G
then the function ImageElm
returns 'fail'.
The input pcpelm is an element
of H.
IsSolvableGroup(
G )
G is a subgroup of GL(d,R) where R=Q,Z or Fq. This function tests if G is solvable and returns 'true' or 'false'.
IsTriangularizableMatGroup(
G )
G is a subgroup of GL(d,Q). This function tests if G is triangularizable and returns 'true' or 'false'.
IsPolycyclicMatGroup(
G )
G is a subgroup of GL(d,R) where R=Q,Z or Fq. This function tests if G is polycyclic and returns 'true' or 'false'.
Let G be a finitely generated solvable subgroup of GL(d,Q). The vector space Qd is a module for the algebra Q[G]. The following functions provide the possibility to compute certain module series of Qd. Recall that the radical RadG(Qd) is defined to be the intersection of maximal Q[G]-submodules of Qd. Also recall that the radical series
0=Rn < Rn-1 < ...< R1 < R0=Qd is defined by Ri+1:= RadG(Ri).
RadicalSeriesSolvableMatGroup(
G )
This function returns a radical series for the Q[G]-module Qd, where G is a solvable subgroup of GL(d,Q).
A radical series of Qd can be refined to a homogeneous series.
HomogeneousSeriesAbelianMatGroup(
G )
A module is said to be homogeneous if it is the direct sum of pairwise irreducible isomorphic submodules. A homogeneous series of a module is a submodule series such that the factors are homogeneous. This function returns a homogeneous series for the Q[G]-module Qd, where G is an abelian subgroup of GL(d,Q).
HomogeneousSeriesTriangularizableMatGroup(
G )
A module is said to be homogeneous if it is the direct sum of pairwise irreducible isomorphic submodules. A homogeneous series of a module is a submodule series such that the factors are homogeneous. This function returns a homogeneous series for the Q[G]-module Qd, where G is a triangularizable subgroup of GL(d,Q).
A homogeneous series can be refined to a composition series.
CompositionSeriesAbelianMatGroup(
G )
A composition series of a module is a submodule series such that the factors are irreducible. This function returns a composition series for the Q[G]-module Qd, where G is an abelian subgroup of GL(d,Q).
CompositionSeriesTriangularizableMatGroup(
G )
A composition series of a module is a submodule series such that the factors are irreducible. This function returns a composition series for the Q[G]-module Qd, where G is a triangularizable subgroup of GL(d,Q).
SubgroupsUnipotentByAbelianByFinite(
G )
G is a subgroup of GL(d,R) where R=Q or Z. If G is polycyclic, then this function returns a record containing two normal subgroups T and U of G. The group T is unipotent-by-abelian (and thus triangularizable) and of finite index in G. The group U is unipotent and is such that T/U is abelian. If G is not polycyclic, then the algorithm returns 'fail'.
PolExamples(
l )
Returns some examples for polycyclic rational matrix groups, where l is an integer between 1 and 24. These can be used to test the functions in this package. Some of the properties of the examples are summarised in the following table.
PolExamples number generators subgroup of Hirsch length 1 3 GL(4,Z) 6 2 2 GL(5,Z) 6 3 2 GL(4,Q) 4 4 2 GL(5,Q) 6 5 9 GL(16,Z) 3 6 6 GL(4,Z) 3 7 6 GL(4,Z) 3 8 7 GL(4,Z) 3 9 5 GL(4,Q) 3 10 4 GL(4,Q) 3 11 5 GL(4,Q) 3 12 5 GL(4,Q) 3 13 5 GL(5,Q) 4 14 6 GL(5,Q) 4 15 6 GL(5,Q) 4 16 5 GL(5,Q) 4 17 5 GL(5,Q) 4 18 5 GL(5,Q) 4 19 5 GL(5,Q) 4 20 7 GL(16,Z) 3 21 5 GL(16,Q) 3 22 4 GL(16,Q) 3 23 5 GL(16,Q) 3 24 5 GL(16,Q) 3
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