Subgroup-defining function

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This article is about a general term. A list of important particular cases (instances) is available at Category: Subgroup-defining functions

Definition

Symbol-free definition

A subgroup-defining function is a rule that sends each group to a subgroup, and such that any isomorphism of groups take the defined subgroup of one group to the defined subgroup for the other.

Definition with symbols

A subgroup-defining function is a rule ${\displaystyle f}$ that sends each group ${\displaystyle G}$ to a subgroup ${\displaystyle f(G)}$. By subgroup here we mean an abstract group along with an embedding into ${\displaystyle G}$. The subgroup-defining function should satisfy the property that whenever there is an isomorphism ${\displaystyle \sigma :G}$ → ${\displaystyle H}$, the image of ${\displaystyle f(G)}$ under ${\displaystyle \sigma }$ is ${\displaystyle f(H)}$.

For particular kinds of groups

Subgroup-defining functions of particular kinds on groups of prime power order are particularly important. A subgroup-defining function on all groups whose order is a power of ${\displaystyle p}$, for a fixed prime ${\displaystyle p}$, that returns nontrivial subgroups for nontrivial groups, is termed a characteristic p-functor. Characteristic p-functors are a special case of conjugacy functors.

Property theory

Subgroup properties satisfied

Further information: subgroup-defining function value is characteristic

Any subgroup-defining function defines a characteristic subgroup. If the function is a verbal function, its defines a verbal subgroup and hence a fully characteristic subgroup, whereas if the function is a word-bound function, it defines a word-bound subgroup and hence a strictly characteristic subgroup.

If the subgroup-defining function is monotone and idempotent, then it is intermediacy-preserved. Thus, if it always satisfies a subgroup property ${\displaystyle p}$, it also always satisfies the property intermediately ${\displaystyle p}$. In particular, any subgroup obtained this way is an intermediately characteristic subgroup.

Associated constructions

Quotient-defining function

To any subgroup-defining function, we can also associate a corresponding quotient-defining function, which sends a group to the quotient group by that subgroup. Note that the quotient group is well-defined because a subgroup-defining function always returns a characteristic subgroup, and every characteristic subgroup is normal.

Descending series

Given a subgroup-defining function, the associated descending series, also called the series obtained by iteration of the subgroup-defining function, is the series that, for any group ${\displaystyle G}$, gives ${\displaystyle G,f(G),f(f(G))...}$.

We can continue this series transfinitely by defining the ${\displaystyle (\alpha +1{)}^{th}}$ term as ${\displaystyle f}$ of the ${\displaystyle {\alpha }^{th}}$ term, and by defining the term for a limit ordinal as the intersection of all its predecessors.

As with any descending series-defining function, we can talk of the length, and the notion of being descendable to the trivial subgroup. Thus, we can associate these notions to any subgroup-defining function.

Ascending series

Given a subgroup-defining function, the associated ascending series, also called the series obtained by quotient-iteration, is defined as PLACEHOLDER FOR INFORMATION TO BE FILLED IN: [SHOW MORE]

As with any ascending series-defining function, we can talk of the length, and the notion of being ascendable to the whole group. Thus, we can associate these notions to any subgroup-defining function.

Operators to group properties

The image operator

The image operator is a map from the collection of subgroup-defining functions to the collection of group properties that sends a subgroup-defining function to the property of being a group that can arise as the result of applying the subgroup-defining function to some group.

The fixed-point operator

The fixed-point operator is a map from the collection of subgroup-defining functions to the collection of group properties that sends a subgroup-defining function to the property of being a group which is fixed point under this subgroup-defining function.

For idempotent subgroup-defining functions, the fixed-point operator and image operator have the same effect.

The free operator

The free operator is a map from the collection of subgroup-defining functions to the collection of group properties. This sends a subgroup-defining function to the property of being a group for which the corresponding subgroup is the trivial subgroup.