User:DanielConstantinMayer/ sandbox
p-group generation algorithm
In mathematics, specifically group theory, finite groups of prime power order , for a fixed prime number and varying integer exponents , are briefly called finite p-groups.
The p-group generation algorithm is a recursive process for constructing the descendant tree of an assigned finite p-group which is taken as the root of the tree.
Additionally to their order , finite p-groups have two further related invariants, the nilpotency class and the coclass .
Lower exponent-p central series
[edit]For a finite p-group , the lower exponent-p central series (briefly lower p-central series) of is a descending series of characteristic subgroups of , defined recursively by and , for . Since any non-trivial finite p-group is nilpotent, there exists an integer such that and is called the exponent-p class (briefly p-class) of . Only the trivial group has . Generally , for any finite p-group , its p-class can be defined as .
The complete series is given by ,
since is the Frattini subgroup of .
For the convenience of the reader and for pointing out the shifted numeration, we recall that the (usual) lower central series of is also a descending series of characteristic subgroups of , defined recursively by and , for . As above, for any non-trivial finite p-group , there exists an integer such that and is called the nilpotency class of , whereas is called the index of nilpotency of . Only the trivial group has .
The complete series is given by ,
since is the commutator subgroup or derived subgroup of .
The following Rules should be remembered for the exponent-p class:
Let be a finite p-group.
- Rule: , since the descend more quickly than the .
- Rule: , for some group , for any .
- Rule: For any , the conditions and imply .
- Rule: For any , , for all , and , for all .
Parents and descendant trees
[edit]The parent of a finite non-trivial p-group with exponent-p class is defined as the quotient of by the last non-trivial term of the lower exponent-p central series of . Conversely, in this case, is called an immediate descendant of . The p-classes of parent and immediate descendant are connected by .
A descendant tree is a hierarchical structure for visualizing parent-descendant relations between isomorphism classes of finite p-groups. The vertices of a descendant tree are isomorphism classes of finite p-groups. However, a vertex will always be labelled by selecting a representative of the corresponding isomorphism class. Whenever a vertex is the parent of a vertex a directed edge of the descendant tree is defined by in the direction of the canonical projection onto the quotient .
In a descendant tree, the concepts of parents and immediate descendants can be generalized. A vertex is a descendant of a vertex , and is an ancestor of , if either is equal to or there is a path , with , of directed edges from to . The vertices forming the path necessarily coincide with the iterated parents of , with . They can also be viewed as the successive quotients of p-class of when the p-class of is given by . In particular, every non-trivial finite p-group defines a maximal path ending in the trivial group . The last but one quotient of the maximal path of is the elementary abelian p-group of rank , where denotes the generator rank of .
Generally, the descendant tree of a vertex is the subtree of all descendants of , starting at the root . The maximal possible descendant tree of the trivial group contains all finite p-groups and is exceptional, since the trivial group has all the infinitely many elementary abelian p-groups with varying generator rank as its immediate descendants. However, any non-trivial finite p-group (of order divisible by ) possesses only finitely many immediate descendants.
p-covering group
[edit]Let be a finite p-group with generators. Our goal is to compile a complete list of pairwise non-isomorphic immediate descendants of . It turned out that all immediate descendants can be obtained as quotients of a certain extension of which is called the p-covering group of and can be constructed in the following manner.
We can certainly find a presentation of in the form of an exact sequence , where denotes the free group with generators and is an epimorphism with kernel . Then is a normal subgroup of consisting of the defining relations for . For elements and , the conjugate and thus also the commutator are contained in . Consequently, is a characteristic subgroup of , and the p-multiplicator of is an elementary abelian p-group, since . Now we can define the p-covering group of by , and the exact sequence shows that is an extension of by the elementary abelian p-multiplicator. We call the p-multiplicator rank of .
Let us assume now that the assigned finite p-group is of p-class . Then the conditions and imply , according to Rule 3, and we can define the nucleus of by as a subgroup of the p-multiplier. Consequently, the nuclear rank of is bounded from above by the p-multiplicator rank.
Allowable subgroups
[edit]Tree Diagram
[edit]A vertex is capable (or extendable) if it has at least one immediate descendant, otherwise it is terminal (or a leaf). Vertices sharing a common parent are called siblings.
Multifurcation and coclass graphs
[edit]Assume that parents of finite p-groups are defined as last non-trivial lower central quotients (2.). For a p-group of coclass , we can distinguish its (entire) descendant tree and its coclass- descendent tree , the subtree consisting of descendants of coclass only. The group is coclass settled if .
The nuclear rank of in the theory of the p-group generation algorithm by E. A. O'Brien [1] provides the following criteria.
- is terminal (and thus trivially coclass settled) if and only if .
- If , then is capable. (But it remains unknown whether is coclass settled.)
- If , then is capable but not coclass settled.
In the last case, a more precise assertion is possible: If has coclass and nuclear rank , then it gives rise to an m-fold multifurcation into a regular coclass-r descendant tree and irregular descendant trees of coclass , for . Consequently, the descendant tree of is the disjoint union .
Multifurcation is correlated with different orders of the last non-trivial lower central of immediate descendants. Since the nilpotency class increases exactly by a unit, , from a parent to any immediate descendant , the coclass remains stable, , if . In this case, is a regular immediate descendant with directed edge of depth 1 (as usual). However, the coclass increases by , if with . Then is called an irregular immediate descendant with directed edge of depth .
If the condition of depth (or step size) 1 is imposed on all directed edges, then the maximal descendant tree of the trivial group splits into a countably infinite disjoint union of directed coclass graphs , which are rather forests than trees. More precisely, the above mentioned Coclass Theorems imply that is the disjoint union of finitely many coclass trees of (pairwise non-isomorphic) infinite pro-p groups of coclass (Theorem D) and a finite subgraph of sporadic groups lying outside of any coclass tree.
Identifiers
[edit]The SmallGroups Library identifiers of finite groups, in particular p-groups, given in the form in the following concrete examples of descendant trees, are due to H. U. Besche, B. Eick and E. A. O'Brien [2]. When the group orders are given in a scale on the left hand side as in Figure 2 and Figure 3, the identifiers are briefly denoted by .
Depending on the prime , there is an upper bound on the order of groups for which a SmallGroup identifier exists, e. g. for , and for . For groups of bigger orders, a notation resembling the descendant structure is employed: A regular immediate descendant, connected by an edge of depth with its parent , is denoted by , and an irregular immediate descendant, connected by an edge of depth with its parent , is denoted by .
Concrete examples
[edit]In all examples, the underlying parent definition (2.) corresponds to the usual lower central series. Occasional differences to the parent definition (3.) with respect to the lower exponent-p central series are pointed out.
Coclass 0
[edit]The coclass graph of finite p-groups of coclass does not contain a coclass tree and consists of the trivial group and the cyclic group of order , which is a leaf (however, it is capable with respect to the lower exponent-p central series). For the SmallGroup identifier of is , for it is .
Coclass 1
[edit]The coclass graph of finite p-groups of coclass consists of the unique coclass tree with root , the elementary abelian p-group of rank , and a single isolated vertex (a terminal orphan without proper parent in the same coclass graph, since the directed edge to the trivial group has depth ), the cyclic group of order in the sporadic part (however, this group is capable with respect to the lower exponent-p central series). The tree is the coclass tree of the unique infinite pro-p group of coclass .
For , resp. , the SmallGroup identifier of the root is , resp. , and a tree diagram of the coclass graph from branch up to branch (counted with respect to the p-logarithm of the order of the branch root) is drawn in Figure 2, resp. Figure 3, where all groups of order at least are metabelian, that is non-abelian with derived length (vertices represented by black discs in contrast to contour squares indicating abelian groups). In Figure 3, smaller black discs denote metabelian 3-groups where even the maximal subgroups are non-abelian, a feature which does not occur for the metabelian 2-groups in Figure 2, since they all possess an abelian subgroup of index (usually exactly one). The coclass tree of , resp. , has periodic root and period of length starting with branch , resp. periodic root and period of length starting with branch . Both trees have branches of bounded depth , so their virtual periodicity is in fact a strict periodicity.
However, the coclass tree of has unbounded depth and contains non-metabelian groups, and the coclass tree of has unbounded depth and even unbounded width, that is the number of descendants of a fixed order increases indefinitely with growing order [3].
The concrete examples and provide an opportunity to give a parametrized power-commutator presentation [4] (here a polycyclic presentation) for the complete coclass tree, mentioned in the lead section as a benefit of the descendant tree concept and as a consequence of the periodicity of the pruned coclass tree. In both cases, the group is generated by two elements but the presentation contains the series of higher commutators , , starting with the main commutator . The nilpotency is formally expressed by , when the group is of order .
For , there are two parameters and the pc-presentation is given by
The 2-groups of maximal class, that is of coclass , form three periodic infinite sequences,
- the dihedral groups, , , forming the mainline (with infinitely capable vertices),
- the generalized quaternion groups, , , which are all terminal vertices,
- the semidihedral groups, , , which are also leaves.
For , there are three parameters and and the pc-presentation is given by
3-groups with parameter possess an abelian maximal subgroup, those with parameter do not. More precisely, an existing abelian maximal subgroup is unique, except for the two groups and , where all four maximal subgroups are abelian.
In contrast to any bigger coclass , the coclass graph exclusively contains p-groups with abelianization of type , except for its unique isolated vertex. The case is distinguished by the truth of the reverse statement: Any -group with abelianization of type is of coclass (O. Taussky's Theorem [5]).
Coclass 2
[edit]The genesis of the coclass graph with is not uniform. p-groups with several distinct abelianizations contribute to its constitution. For coclass , there are essential contributions from groups with abelianizations of the types , , , and an isolated contribution by the cyclic group of order .
Abelianization of type
[edit]As opposed to p-groups of coclass with abelianization of type or , which arise as regular descendants of abelian p-groups of the same types, p-groups of coclass with abelianization of type arise from irregular descendants of a non-abelian p-group of coclass which is not coclass settled.
For the prime , such groups do not exist at all, since the group is coclass-settled, which is the deeper reason for Taussky's Theorem.
For odd primes , the existence of p-groups of coclass with abelianization of type is due to the fact that the group is not coclass-settled. Its nuclear rank equals , which gives rise to a bifurcation of the descendant tree into two coclass graphs. The regular component is a subtree of the unique tree in the coclass graph . The irregular component becomes a subgraph of the coclass graph when the connecting edges of depth of the irregular immediate descendants of are removed.
For , this subgraph is drawn in Figure 4. It has seven top level vertices of three important kinds, all having order .
- Firstly, there are two terminal Schur σ-groups and in the sporadic part of the coclass graph .
- Secondly, the two groups and are roots of finite trees in .
- And, finally, the three groups , and give rise to (infinite) coclass trees in the coclass graph .
Generally, a Schur group (called a closed group by I. Schur, who coined the concept) is a pro-p group whose relation rank coincides with its generator rank . A σ-group is a pro-p group which possesses an automorphism inducing the inversion on the abelianization . A Schur σ-group is a Schur group which is also a σ-group and has a finite abelianization .
History
[edit]Descendant trees with central quotients as parents (1.) are implicit in P. Hall's 1940 paper [6] about isoclinism of groups. Trees with last non-trivial lower central quotients as parents (2.) were first presented by C. R. Leedham-Green at the International Congress of Mathematicians in Vancouver, 1974 [7]. The first extensive tree diagrams have been drawn manually by J. A. Ascione, G. Havas and C. R. Leedham-Green (1977) [8], by J. A. Ascione (1979) [9], and by B. Nebelung (1989) [10]. In the former two cases, the parent definition by means of the lower exponent-p central series (3.) was adopted in view of computational advantages, in the latter case, where theoretical aspects were focussed, the parents were taken with respect to the usual lower central series (2.).
References
[edit]- ^ O'Brien, E. A. (1990). "The p-group generation algorithm". J. Symbolic Comput. 9: 677–698.
- ^
Besche, H. U., Eick, B., O'Brien, E. A. (2005). The SmallGroups Library - a library of groups of small order. An accepted and refereed GAP 4 package, available also in MAGMA.
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: CS1 maint: multiple names: authors list (link) - ^
Dietrich, H., Eick, B., Feichtenschlager, D. (2008). "Investigating p-groups by coclass with GAP". Contemporary Mathematics, Computational group theory and the theory of groups. 470: 45–61.
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: CS1 maint: multiple names: authors list (link) - ^ Blackburn, N. (1958). "On a special class of p-groups". Acta Math. 100: 45–92.
- ^ Taussky, O. (1937). "A remark on the class field tower". J. London Math. Soc. 12: 82–85.
- ^ Hall, P. (1940). "The classification of prime-power groups". J. Reine Angew. Math. 182: 130–141.
- ^ Cite error: The named reference
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Ascione, J. A., Havas, G., Leedham-Green, C. R. (1977). "A computer aided classification of certain groups of prime power order". Bull. Austral. Math. Soc. 17: 257–274.
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: CS1 maint: multiple names: authors list (link) - ^ Ascione, J. A. (1979). On 3-groups of second maximal class. Ph. D. Thesis, Australian National University, Canberra.
- ^ Nebelung, B. (1989). Klassifikation metabelscher 3-Gruppen mit Faktorkommutatorgruppe vom Typ (3,3) und Anwendung auf das Kapitulationsproblem. Inauguraldissertation, Universität zu Köln.
Category: group theory Category: P-groups Category: Subgroup series Category: Trees (data structures)