العربية
中国
Français
Deutsch
Ελληνική
हिन्दी
Italiano
日本語
Português
Русский
EspañolGRADED ALGEBRA
In mathematics, in particular abstract algebra, a 'graded algebra' is an algebra over a field (or commutative ring) with an extra piece of structure, known as a 'gradation' (or ''grading'').
A 'graded ring' ''A'' is a ring that has a direct sum decomposition into (abelian) additive groups
:
such that the ring multiplication maps
:
Explicitly this means that whenever
:
and so
:
Elements of are known as ''homogeneous elements'' of degree ''n''. An ideal or other subset ⊂ ''A'' is 'homogeneous' if for every element ''a'' ∈ , the homogeneous parts of ''a'' are also contained in
If ''I'' is a homogeneous ideal in ''A'', then is also a graded ring, and has decomposition
:.
Any (non-graded) ring ''A'' can be given a gradation by letting ''A''0 = ''A'', and ''A''''i'' = 0 for ''i'' > 0. This is called the 'trivial gradation' on ''A''.
The corresponding idea in module theory is that of a 'graded module', namely a module ''M'' over a graded ring ''A'' such that also
:
and
:
This idea is much used in commutative algebra, and elsewhere, to define under mild hypotheses a 'Hilbert function', namely the length of ''M''''n'' as a function of ''n''. Again under mild hypotheses of finiteness, this function is a polynomial, the Hilbert polynomial, for all large enough values of ''n'' (see also Hilbert-Samuel polynomial).
A graded algebra over a graded ring ''A'' is an ''A''-algebra ''E'' which is both a graded ''A''-module and a graded ring in its own right. Thus ''E'' admits a direct sum decomposition
::
such that
#''A''i''E''j ⊂ ''E''i+j, and
#''E''i''E''j ⊂ ''E''i+j.
Often when no grading on ''A'' is specified, it is assumed that ''A'' receives the trivial gradation, in which case one may still talk about graded algebras over ''A'' without risk of confusion.
Examples of graded algebras are common in mathematics:
★ Polynomial rings. The homogeneous elements of degree ''n'' are exactly the homogeneous polynomials of degree ''n''.
★ The tensor algebra ''T''•''V'' of a vector space ''V''. The homogeneous elements of degree ''n'' are the tensors of rank ''n'', ''T''''n''''V''.
★ The exterior algebra Λ•''V'' and symmetric algebra ''S''•''V'' are also graded algebras.
★ The cohomology ring ''H''• in any cohomology theory is also graded, being the direct sum of the ''H''''n''.
Graded algebras are much used in commutative algebra and algebraic geometry, homological algebra and algebraic topology. One example is the close relationship between homogeneous polynomials and projective varieties.
We can generalize the definition of a graded ring using any monoid ''G'' as an index set. A '''G''-graded ring' ''A'' is a ring with a direct sum decomposition
:
such that
:
Remarks:
★ A graded algebra is then the same thing as a 'N'-graded algebra, where 'N' is the monoid of non-negative integers.
★ If we do not require that the ring have an identity element, semigroups may replace monoids.
★ ''G''-graded modules and algebras are defined in the same fashion as above.
Examples:
★ A group naturally grades the corresponding group ring; similarly, monoid rings are graded by the corresponding monoid.
★ A superalgebra is another term for a 'Z'2-graded algebra. Examples include Clifford algebras. Here the homogeneous elements are either of degree 0 (even) or 1 (odd).
In category theory, a ''G''-graded algebra ''A'' is an object in the category of ''G''-graded vector spaces, together with a morphism of the degree of the identity of ''G''.
Some graded rings (or algebras) are endowed with an anticommutative structure. This notion requires the use of a semiring to supply the gradation rather than a monoid. Specifically, a 'signed semiring' consists of a pair (Γ, ε) where Γ is a semiring and ε : Γ → 'Z'/2'Z' is a homomorphism of additive monoids. An 'anticommutative Γ-graded ring' is a ring ''A'' graded with respect to the ''additive'' structure on Γ such that:
:xy=(-1)ε (deg x) ε (deg y)yx, for all homogeneous elements ''x'' and ''y''.
★ An exterior algebra is an example of an anticommutative algebra, graded with respect to the structure ('Z'≥ 0, ε) where ε is the homomorphism given by ε(''even'') = 0, ε(''odd'') = 1.
★ A supercommutative algebra (sometimes called a 'skew-commutative associative ring') is the same thing as an anticommutative ('Z'/2'Z', ε) -graded algebra, where ε is the identity endomorphism for the additive structure.
★ graded vector space
★ graded category
★ differential graded algebra
★ graded Lie algebra
| Contents |
| Graded rings |
| Graded modules |
| Graded algebras |
| G-graded rings and algebras |
| Anticommutativity |
| Examples |
| See also |
Graded rings
A 'graded ring' ''A'' is a ring that has a direct sum decomposition into (abelian) additive groups
:
such that the ring multiplication maps
:
Explicitly this means that whenever
:
and so
:
Elements of are known as ''homogeneous elements'' of degree ''n''. An ideal or other subset ⊂ ''A'' is 'homogeneous' if for every element ''a'' ∈ , the homogeneous parts of ''a'' are also contained in
If ''I'' is a homogeneous ideal in ''A'', then is also a graded ring, and has decomposition
:.
Any (non-graded) ring ''A'' can be given a gradation by letting ''A''0 = ''A'', and ''A''''i'' = 0 for ''i'' > 0. This is called the 'trivial gradation' on ''A''.
Graded modules
The corresponding idea in module theory is that of a 'graded module', namely a module ''M'' over a graded ring ''A'' such that also
:
and
:
This idea is much used in commutative algebra, and elsewhere, to define under mild hypotheses a 'Hilbert function', namely the length of ''M''''n'' as a function of ''n''. Again under mild hypotheses of finiteness, this function is a polynomial, the Hilbert polynomial, for all large enough values of ''n'' (see also Hilbert-Samuel polynomial).
Graded algebras
A graded algebra over a graded ring ''A'' is an ''A''-algebra ''E'' which is both a graded ''A''-module and a graded ring in its own right. Thus ''E'' admits a direct sum decomposition
::
such that
#''A''i''E''j ⊂ ''E''i+j, and
#''E''i''E''j ⊂ ''E''i+j.
Often when no grading on ''A'' is specified, it is assumed that ''A'' receives the trivial gradation, in which case one may still talk about graded algebras over ''A'' without risk of confusion.
Examples of graded algebras are common in mathematics:
★ Polynomial rings. The homogeneous elements of degree ''n'' are exactly the homogeneous polynomials of degree ''n''.
★ The tensor algebra ''T''•''V'' of a vector space ''V''. The homogeneous elements of degree ''n'' are the tensors of rank ''n'', ''T''''n''''V''.
★ The exterior algebra Λ•''V'' and symmetric algebra ''S''•''V'' are also graded algebras.
★ The cohomology ring ''H''• in any cohomology theory is also graded, being the direct sum of the ''H''''n''.
Graded algebras are much used in commutative algebra and algebraic geometry, homological algebra and algebraic topology. One example is the close relationship between homogeneous polynomials and projective varieties.
G-graded rings and algebras
We can generalize the definition of a graded ring using any monoid ''G'' as an index set. A '''G''-graded ring' ''A'' is a ring with a direct sum decomposition
:
such that
:
Remarks:
★ A graded algebra is then the same thing as a 'N'-graded algebra, where 'N' is the monoid of non-negative integers.
★ If we do not require that the ring have an identity element, semigroups may replace monoids.
★ ''G''-graded modules and algebras are defined in the same fashion as above.
Examples:
★ A group naturally grades the corresponding group ring; similarly, monoid rings are graded by the corresponding monoid.
★ A superalgebra is another term for a 'Z'2-graded algebra. Examples include Clifford algebras. Here the homogeneous elements are either of degree 0 (even) or 1 (odd).
In category theory, a ''G''-graded algebra ''A'' is an object in the category of ''G''-graded vector spaces, together with a morphism of the degree of the identity of ''G''.
Anticommutativity
Some graded rings (or algebras) are endowed with an anticommutative structure. This notion requires the use of a semiring to supply the gradation rather than a monoid. Specifically, a 'signed semiring' consists of a pair (Γ, ε) where Γ is a semiring and ε : Γ → 'Z'/2'Z' is a homomorphism of additive monoids. An 'anticommutative Γ-graded ring' is a ring ''A'' graded with respect to the ''additive'' structure on Γ such that:
:xy=(-1)ε (deg x) ε (deg y)yx, for all homogeneous elements ''x'' and ''y''.
Examples
★ An exterior algebra is an example of an anticommutative algebra, graded with respect to the structure ('Z'≥ 0, ε) where ε is the homomorphism given by ε(''even'') = 0, ε(''odd'') = 1.
★ A supercommutative algebra (sometimes called a 'skew-commutative associative ring') is the same thing as an anticommutative ('Z'/2'Z', ε) -graded algebra, where ε is the identity endomorphism for the additive structure.
See also
★ graded vector space
★ graded category
★ differential graded algebra
★ graded Lie algebra
This article provided by Wikipedia. To edit the contents of this article, click here for original source.
psst.. try this: add to faves
