Difference between revisions of "Derived functor"
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A functor "measuring" the deviation of a given functor from being exact. Let $ T ( A , C ) $ | A functor "measuring" the deviation of a given functor from being exact. Let $ T ( A , C ) $ | ||
− | be an additive functor from the product of the category of $ R _ {1} $- | + | be an additive functor from the product of the category of $ R _ {1} $-modules with the category of $ R _ {2} $-modules into the category of $ R $-modules that is covariant in the first argument and contravariant in the second argument. From an injective resolution $ X $ |
− | modules with the category of $ R _ {2} $- | ||
− | modules into the category of $ R $- | ||
− | modules that is covariant in the first argument and contravariant in the second argument. From an injective resolution $ X $ | ||
of $ A $ | of $ A $ | ||
and a projective resolution $ Y $ | and a projective resolution $ Y $ | ||
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$$ | $$ | ||
\rightarrow \ | \rightarrow \ | ||
− | R ^ {n+} | + | R ^ {n+ 1} T ( A ^ \prime , C ) \rightarrow \dots |
$$ | $$ | ||
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$$ | $$ | ||
\rightarrow \ | \rightarrow \ | ||
− | R ^ {n+} | + | R ^ {n+ 1} T ( A , C ^ {\prime\prime} ) \rightarrow \dots , |
$$ | $$ | ||
Latest revision as of 07:09, 10 May 2022
A functor "measuring" the deviation of a given functor from being exact. Let $ T ( A , C ) $
be an additive functor from the product of the category of $ R _ {1} $-modules with the category of $ R _ {2} $-modules into the category of $ R $-modules that is covariant in the first argument and contravariant in the second argument. From an injective resolution $ X $
of $ A $
and a projective resolution $ Y $
of $ C $
one obtains a doubly-graded complex $ T( X , Y ) $.
The homology of the associated single complex $ T ( A , C ) $
does not depend on the choice of resolutions, has functorial properties and is called the right derived functor $ R ^ {n} T ( A , C ) $
of $ T ( A , C ) $.
The basic property of a derived functor is the existence of long exact sequences
$$ \rightarrow R ^ {n} T ( A ^ \prime , C ) \rightarrow R ^ {n} T ( A , C ) \rightarrow R ^ {n} T ( A ^ {\prime\prime} , C ) \rightarrow $$
$$ \rightarrow \ R ^ {n+ 1} T ( A ^ \prime , C ) \rightarrow \dots $$
$$ \rightarrow R ^ {n} T ( A , C ^ {\prime\prime} ) \rightarrow R ^ {n} T ( A , C ) \rightarrow R ^ {n} T ( A , C ^ \prime ) \rightarrow $$
$$ \rightarrow \ R ^ {n+ 1} T ( A , C ^ {\prime\prime} ) \rightarrow \dots , $$
induced by short exact sequences
$$ 0 \rightarrow A ^ \prime \rightarrow A \rightarrow A ^ {\prime\prime} \rightarrow 0, $$
$$ 0 \rightarrow C ^ \prime \rightarrow C \rightarrow C ^ {\prime\prime} \rightarrow 0 . $$
The left derived functor is defined analogously. The derived functor of $ \mathop{\rm Hom} _ {R} $ is denoted by $ \mathop{\rm Ext} _ {R} ^ {n} $. The group $ \mathop{\rm Ext} _ {R} ^ {1} ( A , C ) $ classifies extensions of $ A $ with kernel $ C $ up to equivalence (cf. Baer multiplication; Cohomology of algebras).
References
[1] | H. Cartan, S. Eilenberg, "Homological algebra" , Princeton Univ. Press (1956) |
[2] | S. MacLane, "Homology" , Springer (1963) |
Comments
The above article does not explain the sense in which $ R ^ {n} T $ measures the deviation of $ T $ from being exact. The point is that if $ T $ is left exact (i.e. preserves the exactness of sequences of the form $ 0 \rightarrow A ^ \prime \rightarrow A \rightarrow A ^ {\prime\prime} $ in the fist variable and of the form $ C ^ \prime \rightarrow C \rightarrow C ^ {\prime\prime} \rightarrow 0 $ in the second), then $ R ^ {0} T $ is naturally isomorphic to $ T $; if further $ T $ is exact, then $ R ^ {n} T = 0 $ for all $ n > 0 $. Derived functors may also be defined for additive functors of a single variable between module categories, or, more generally, between arbitrary Abelian categories, provided the necessary injective or projective resolutions exist in the domain category.
Derived functor. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Derived_functor&oldid=52352