Difference between revisions of "Imprimitive group"
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of one-to-one mappings (permutations, cf. [[Permutation|Permutation]]) of a set $ S $ | of one-to-one mappings (permutations, cf. [[Permutation|Permutation]]) of a set $ S $ | ||
onto itself, for which there exists a partition of $ S $ | onto itself, for which there exists a partition of $ S $ | ||
− | into a union of disjoint subsets $ S _ {1} \dots S _ {m} $, | + | into a union of disjoint subsets $ S _ {1}, \dots, S _ {m} $, |
$ m \geq 2 $, | $ m \geq 2 $, | ||
with the following properties: the number of elements in at least one of the sets $ S _ {i} $ | with the following properties: the number of elements in at least one of the sets $ S _ {i} $ | ||
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onto $ S _ {j} $. | onto $ S _ {j} $. | ||
− | The collection of subsets $ S _ {1} \dots S _ {m} $ | + | The collection of subsets $ S _ {1}, \dots, S _ {m} $ |
is called a system of imprimitivity, while the subsets $ S _ {i} $ | is called a system of imprimitivity, while the subsets $ S _ {i} $ | ||
themselves are called domains of imprimitivity of the group $ G $. | themselves are called domains of imprimitivity of the group $ G $. | ||
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An example of an imprimitive group is a non-trivial intransitive group $ G $ | An example of an imprimitive group is a non-trivial intransitive group $ G $ | ||
− | of permutations of a set $ S $( | + | of permutations of a set $ S $ (see [[Transitive group|Transitive group]]): for a system of imprimitivity one can take the collection of all orbits (domains of transitivity, cf. [[Orbit|Orbit]]) of $ G $ |
− | see [[Transitive group|Transitive group]]): for a system of imprimitivity one can take the collection of all orbits (domains of transitivity, cf. [[Orbit|Orbit]]) of $ G $ | ||
on $ S $. | on $ S $. | ||
A transitive group of permutations $ G $ | A transitive group of permutations $ G $ | ||
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is called imprimitive if there exists a decomposition of the space $ V $ | is called imprimitive if there exists a decomposition of the space $ V $ | ||
of the representation $ \rho $ | of the representation $ \rho $ | ||
− | into a direct sum of proper subspaces $ V _ {1} \dots V _ {m} $ | + | into a direct sum of proper subspaces $ V _ {1}, \dots, V _ {m} $ |
with the following property: For any $ g \in G $ | with the following property: For any $ g \in G $ | ||
and any $ i $, | and any $ i $, | ||
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$$ | $$ | ||
− | The collection of subsets $ V _ {1} \dots V _ {m} $ | + | The collection of subsets $ V _ {1}, \dots, V _ {m} $ |
is called a system of imprimitivity of the representation $ \rho $. | is called a system of imprimitivity of the representation $ \rho $. | ||
If $ V $ | If $ V $ | ||
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The group $ \rho ( G) $ | The group $ \rho ( G) $ | ||
of linear transformations of the space $ V $ | of linear transformations of the space $ V $ | ||
− | and the $ G $- | + | and the $ G $-module $ V $ |
− | module $ V $ | ||
defined by the representation $ \rho $ | defined by the representation $ \rho $ | ||
are also called imprimitive (or primitive) if the representation $ \rho $ | are also called imprimitive (or primitive) if the representation $ \rho $ | ||
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Examples. A representation $ \rho $ | Examples. A representation $ \rho $ | ||
of the symmetric group $ S _ {n} $ | of the symmetric group $ S _ {n} $ | ||
− | in the $ n $- | + | in the $ n $-dimensional vector space over a field $ k $ |
− | dimensional vector space over a field $ k $ | + | that rearranges the elements of a basis $ e _ {1}, \dots, e _ {n} $ |
− | that rearranges the elements of a basis $ e _ {1} \dots e _ {n} $ | + | is transitive imprimitive, the one-dimensional subspaces $ \{ k e _ {1}, \dots, k e _ {n} \} $ |
− | is transitive imprimitive, the one-dimensional subspaces $ \{ k e _ {1} \dots k e _ {n} \} $ | ||
form a system of imprimitivity for $ \rho $. | form a system of imprimitivity for $ \rho $. | ||
Another example of a transitive imprimitive representation is the [[Regular representation|regular representation]] of a finite group $ G $ | Another example of a transitive imprimitive representation is the [[Regular representation|regular representation]] of a finite group $ G $ | ||
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The notion of an imprimitive representation is closely related to that of an [[Induced representation|induced representation]]. Namely, let $ \rho $ | The notion of an imprimitive representation is closely related to that of an [[Induced representation|induced representation]]. Namely, let $ \rho $ | ||
be an imprimitive finite-dimensional representation of a finite group $ G $ | be an imprimitive finite-dimensional representation of a finite group $ G $ | ||
− | with system of imprimitivity $ \{ V _ {1} \dots V _ {n} \} $. | + | with system of imprimitivity $ \{ V _ {1}, \dots, V _ {n} \} $. |
− | The set $ \{ V _ {1} \dots V _ {n} \} $ | + | The set $ \{ V _ {1}, \dots, V _ {n} \} $ |
is partitioned into a union of orbits with respect to the action of $ G $ | is partitioned into a union of orbits with respect to the action of $ G $ | ||
determined by $ \rho $. | determined by $ \rho $. | ||
− | Let $ \{ V _ {i _ {1} } \dots V _ {i _ {s} } \} $ | + | Let $ \{ V _ {i _ {1} }, \dots, V _ {i _ {s} } \} $ |
be a complete set of representatives of the different orbits of this action, let | be a complete set of representatives of the different orbits of this action, let | ||
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H _ {m} = \ | H _ {m} = \ | ||
\{ {g \in G } : {\rho ( g) ( V _ {i _ {m} } ) = V _ {i _ {m} } } \} | \{ {g \in G } : {\rho ( g) ( V _ {i _ {m} } ) = V _ {i _ {m} } } \} | ||
− | ,\ m = 1 \dots s , | + | ,\ m = 1, \dots, s , |
$$ | $$ | ||
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induced by $ \phi _ {m} $. | induced by $ \phi _ {m} $. | ||
Then $ \rho $ | Then $ \rho $ | ||
− | is equivalent to the direct sum of the representations $ \rho _ {1} \dots \rho _ {s} $. | + | is equivalent to the direct sum of the representations $ \rho _ {1}, \dots, \rho _ {s} $. |
− | Conversely, let $ H _ {1} \dots H _ {s} $ | + | Conversely, let $ H _ {1}, \dots, H _ {s} $ |
be any collection of subgroups of $ G $, | be any collection of subgroups of $ G $, | ||
let $ \phi _ {m} $ | let $ \phi _ {m} $ | ||
be a representation of $ H _ {m} $ | be a representation of $ H _ {m} $ | ||
in a finite-dimensional vector space $ W _ {m} $, | in a finite-dimensional vector space $ W _ {m} $, | ||
− | $ m = 1 \dots s $, | + | $ m = 1, \dots, s $, |
and let $ \rho _ {m} $ | and let $ \rho _ {m} $ | ||
be the representation of $ G $ | be the representation of $ G $ | ||
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is a system of representatives of left cosets of $ G $ | is a system of representatives of left cosets of $ G $ | ||
with respect to $ H _ {m} $. | with respect to $ H _ {m} $. | ||
− | Then the direct sum of the representations $ \rho _ {1} \dots \rho _ {s} $ | + | Then the direct sum of the representations $ \rho _ {1}, \dots, \rho _ {s} $ |
is imprimitive, while $ \rho ( g _ {m,j} ) ( W _ {m} ) $, | is imprimitive, while $ \rho ( g _ {m,j} ) ( W _ {m} ) $, | ||
− | $ j = 1 \dots r _ {m} $, | + | $ j = 1, \dots, r _ {m} $, |
− | $ m = 1 \dots s $, | + | $ m = 1, \dots, s $, |
is a system of imprimitivity (here $ W _ {m} $ | is a system of imprimitivity (here $ W _ {m} $ | ||
is canonically identified with a subspace of $ V $). | is canonically identified with a subspace of $ V $). |
Latest revision as of 07:41, 26 February 2022
A group $ G $
of one-to-one mappings (permutations, cf. Permutation) of a set $ S $
onto itself, for which there exists a partition of $ S $
into a union of disjoint subsets $ S _ {1}, \dots, S _ {m} $,
$ m \geq 2 $,
with the following properties: the number of elements in at least one of the sets $ S _ {i} $
is greater than $ 1 $;
for any permutation $ g \in G $
and any $ i $,
$ 1 \leq i \leq m $,
there exists a $ j $,
$ 1 \leq j \leq m $,
such that $ g $
maps $ S _ {i} $
onto $ S _ {j} $.
The collection of subsets $ S _ {1}, \dots, S _ {m} $ is called a system of imprimitivity, while the subsets $ S _ {i} $ themselves are called domains of imprimitivity of the group $ G $. A non-imprimitive group of permutations is called primitive.
An example of an imprimitive group is a non-trivial intransitive group $ G $ of permutations of a set $ S $ (see Transitive group): for a system of imprimitivity one can take the collection of all orbits (domains of transitivity, cf. Orbit) of $ G $ on $ S $. A transitive group of permutations $ G $ of a set $ S $ is primitive if and only if for some element (and hence for all elements) $ y \in S $ the set of permutations of $ G $ leaving $ y $ fixed is a maximal subgroup of $ G $.
The notion of an imprimitive group of permutations has an analogue for groups of linear transformations of vector spaces. Namely, a linear representation $ \rho $ of a group $ G $ is called imprimitive if there exists a decomposition of the space $ V $ of the representation $ \rho $ into a direct sum of proper subspaces $ V _ {1}, \dots, V _ {m} $ with the following property: For any $ g \in G $ and any $ i $, $ 1 \leq i \leq m $, there exists a $ j $, $ 1 \leq j \leq m $, such that
$$ \rho ( g) ( V _ {i} ) = \ V _ {j} . $$
The collection of subsets $ V _ {1}, \dots, V _ {m} $ is called a system of imprimitivity of the representation $ \rho $. If $ V $ does not have a decomposition of the above type, then $ \rho $ is said to be a primitive representation. An imprimitive representation $ \rho $ is called transitive imprimitive if there exists for any pair of subspaces $ V _ {i} $ and $ V _ {j} $ of the system of imprimitivity an element $ g \in G $ such that $ \rho ( g) ( V _ {i} ) = V _ {j} $. The group $ \rho ( G) $ of linear transformations of the space $ V $ and the $ G $-module $ V $ defined by the representation $ \rho $ are also called imprimitive (or primitive) if the representation $ \rho $ is imprimitive (or primitive).
Examples. A representation $ \rho $ of the symmetric group $ S _ {n} $ in the $ n $-dimensional vector space over a field $ k $ that rearranges the elements of a basis $ e _ {1}, \dots, e _ {n} $ is transitive imprimitive, the one-dimensional subspaces $ \{ k e _ {1}, \dots, k e _ {n} \} $ form a system of imprimitivity for $ \rho $. Another example of a transitive imprimitive representation is the regular representation of a finite group $ G $ over a field $ k $; the collection of one-dimensional subspaces $ k g $, where $ g $ runs through $ G $, forms a system of imprimitivity. More generally, any monomial representation of a finite group is imprimitive. The representation of a cyclic group of order $ m \geq 3 $ by rotations of the real plane through angles that are multiples of $ 2 \pi / m $ is primitive.
The notion of an imprimitive representation is closely related to that of an induced representation. Namely, let $ \rho $ be an imprimitive finite-dimensional representation of a finite group $ G $ with system of imprimitivity $ \{ V _ {1}, \dots, V _ {n} \} $. The set $ \{ V _ {1}, \dots, V _ {n} \} $ is partitioned into a union of orbits with respect to the action of $ G $ determined by $ \rho $. Let $ \{ V _ {i _ {1} }, \dots, V _ {i _ {s} } \} $ be a complete set of representatives of the different orbits of this action, let
$$ H _ {m} = \ \{ {g \in G } : {\rho ( g) ( V _ {i _ {m} } ) = V _ {i _ {m} } } \} ,\ m = 1, \dots, s , $$
let $ \phi _ {m} $ be the representation of the group $ H _ {m} $ in $ V _ {i _ {m} } $ defined by the restriction of $ \rho $ to $ H _ {m} $, and let $ \rho _ {m} $ be the representation of $ G $ induced by $ \phi _ {m} $. Then $ \rho $ is equivalent to the direct sum of the representations $ \rho _ {1}, \dots, \rho _ {s} $. Conversely, let $ H _ {1}, \dots, H _ {s} $ be any collection of subgroups of $ G $, let $ \phi _ {m} $ be a representation of $ H _ {m} $ in a finite-dimensional vector space $ W _ {m} $, $ m = 1, \dots, s $, and let $ \rho _ {m} $ be the representation of $ G $ induced by $ \phi _ {m} $. Suppose further that $ \{ g _ {m,j} \} _ {j=} 1 ^ {r _ {m} } $ is a system of representatives of left cosets of $ G $ with respect to $ H _ {m} $. Then the direct sum of the representations $ \rho _ {1}, \dots, \rho _ {s} $ is imprimitive, while $ \rho ( g _ {m,j} ) ( W _ {m} ) $, $ j = 1, \dots, r _ {m} $, $ m = 1, \dots, s $, is a system of imprimitivity (here $ W _ {m} $ is canonically identified with a subspace of $ V $).
References
[1] | M. Hall, "Group theory" , Macmillan (1959) |
[2] | C.W. Curtis, I. Reiner, "Representation theory of finite groups and associative algebras" , Interscience (1962) |
Comments
A domain of imprimitivity is also called a block.
Imprimitive group. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Imprimitive_group&oldid=52130