Difference between revisions of "Faithful functor"
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| − | A [[Functor|functor]] which is "injective on Hom-sets" . Explicitly, a functor | + | <!-- |
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| + | $#C+1 = 12 : ~/encyclopedia/old_files/data/F038/F.0308160 Faithful functor | ||
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| + | A [[Functor|functor]] which is "injective on Hom-sets" . Explicitly, a functor $ F : \mathfrak C \rightarrow \mathfrak D $ | ||
| + | is called faithful if, given any two morphisms $ \alpha , \beta : A \rightarrow B $ | ||
| + | in $ \mathfrak C $ | ||
| + | with the same domain and codomain, the equation $ F \alpha = F \beta $ | ||
| + | implies $ \alpha = \beta $. | ||
| + | The name derives from the representation theory of groups: a permutation (respectively, $ R $- | ||
| + | linear) representation of a group $ G $ | ||
| + | is faithful if and only if it is faithful when considered as a functor $ G \rightarrow \mathop{\rm Set} $( | ||
| + | respectively $ G \rightarrow \mathop{\rm Mod} _ {R} $). | ||
| + | A faithful functor reflects monomorphisms (that is, $ F \alpha $ | ||
| + | monic implies $ \alpha $ | ||
| + | monic) and epimorphisms; hence if the domain category $ \mathfrak C $ | ||
| + | is [[Balanced category|balanced]] (i.e. has the property that any morphism which is both monic and epic is an isomorphism) then it also reflects isomorphisms. A functor with the latter property is generally called conservative; however, some authors include this condition in the definition of faithfulness. | ||
In Russian literature there seems to be some confusion between the terms "faithful functor" and "exact functor" , see also [[Exact functor|Exact functor]]. | In Russian literature there seems to be some confusion between the terms "faithful functor" and "exact functor" , see also [[Exact functor|Exact functor]]. | ||
Latest revision as of 19:41, 20 January 2021
A functor which is "injective on Hom-sets" . Explicitly, a functor $ F : \mathfrak C \rightarrow \mathfrak D $
is called faithful if, given any two morphisms $ \alpha , \beta : A \rightarrow B $
in $ \mathfrak C $
with the same domain and codomain, the equation $ F \alpha = F \beta $
implies $ \alpha = \beta $.
The name derives from the representation theory of groups: a permutation (respectively, $ R $-
linear) representation of a group $ G $
is faithful if and only if it is faithful when considered as a functor $ G \rightarrow \mathop{\rm Set} $(
respectively $ G \rightarrow \mathop{\rm Mod} _ {R} $).
A faithful functor reflects monomorphisms (that is, $ F \alpha $
monic implies $ \alpha $
monic) and epimorphisms; hence if the domain category $ \mathfrak C $
is balanced (i.e. has the property that any morphism which is both monic and epic is an isomorphism) then it also reflects isomorphisms. A functor with the latter property is generally called conservative; however, some authors include this condition in the definition of faithfulness.
In Russian literature there seems to be some confusion between the terms "faithful functor" and "exact functor" , see also Exact functor.
References
| [a1] | B. Mitchell, "Theory of categories" , Acad. Press (1965) |
Faithful functor. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Faithful_functor&oldid=17844