In
category theory, a branch of
mathematics,
group objects are certain generalizations of groups that are built on more complicated structures than sets. A typical example of a group object is a topological group, a group whose underlying set is a topological space such that the group operations are continuous.
Definition
Formally, we start with a category
C with finite products (i.e.
C has a
terminal object 1 and any two objects of
C have a product). A
group object in
C is an object
G of
C together with
-
m : G × G → G (thought of as the "group multiplication")
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e : 1 → G (thought of as the "inclusion of the identity element")
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inv : G → G (thought of as the "inversion operation")
such that the following properties (modeled on the group axioms – more precisely, on the definition of a group used in universal algebra) are satisfied
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m is associative, i.e. m ( m × id G) = m (id G × m) as morphisms G × G × G → G, and where e.g. m × id G : G × G × G → G × G; here we identify G × ( G × G) in a canonical manner with ( G × G) × G.
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e is a two-sided unit of m, i.e. m (id G × e) = p1, where p1 : G × 1 → G is the canonical projection, and m ( e × id G) = p2, where p2 : 1 × G → G is the canonical projection
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inv is a two-sided inverse for m, i.e. if d : G → G × G is the diagonal map, and e G : G → G is the composition of the unique morphism G → 1 (also called the counit) with e, then m (id G × inv) d = e G and m ( inv × id G) d = e G.
Note that this is stated in terms of maps – product and inverse must be maps in the category – and without any reference to underlying "elements" of the group object – categories in general do not have elements of their objects.
Another way to state the above is to say G is a group object in a category C if for every object X in C, there is a group structure on the morphisms Hom( X, G) from X to G such that the association of X to Hom( X, G) is a (contravariant) functor from C to the category of groups.
Yet another way to state the above is to define a group object as a monoid object in the cartesian monoidal category (that is, the monoidal category where the product is × and the unit is the terminal object 1), together with an inverse morphism satisfying the above conditions.
Examples
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Each set G for which a group structure ( G, m, u, −1) can be defined can be considered a group object in the category of set theory. The map m is the group operation, the map e (whose domain is a singleton) picks out the identity element u of G, and the map inv assigns to every group element its inverse. e G : G → G is the map that sends every element of G to the identity element.
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A topological group is a group object in the category of topology with continuous functions.
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A Lie group is a group object in the category of manifold with .
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A Lie supergroup is a group object in the category of .
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An algebraic group is a group object in the category of algebraic varieties. In modern algebraic geometry, one considers the more general , group objects in the category of schemes.
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A localic group is a group object in the category of locales.
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The group objects in the category of groups (or ) are the . The reason for this is that, if inv is assumed to be a homomorphism, then G must be abelian. More precisely: if A is an abelian group and we denote by m the group multiplication of A, by e the inclusion of the identity element, and by inv the inversion operation on A, then ( A, m, e, inv) is a group object in the category of groups (or monoids). Conversely, if ( A, m, e, inv) is a group object in one of those categories, then m necessarily coincides with the given operation on A, e is the inclusion of the given identity element on A, inv is the inversion operation and A with the given operation is an abelian group. See also Eckmann–Hilton argument.
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The strict 2-group is the group object in the category of small categories.
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Given a category C with finite , a cogroup object is an object G of C together with a "comultiplication" m: G → G G, a "coidentity" e: G → 0, and a "coinversion" inv: G → G that satisfy the dual versions of the axioms for group objects. Here 0 is the initial object of C. Cogroup objects occur naturally in algebraic topology.
See also
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can be seen as a generalization of group objects to monoidal categories.
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Groupoid object
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internal category
