mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...

, a graded vector space is a vector space that has the extra structure of a '' grading'' or a ''gradation'', which is a decomposition of the vector space into a

direct sum The direct sum is an operation between structures in abstract algebra, a branch of mathematics. It is defined differently, but analogously, for different kinds of structures. To see how the direct sum is used in abstract algebra, consider a more ...

of vector subspaces.

Integer gradation

Let

\mathbb

be the set of non-negative integers. An

\mathbb

-graded vector space, often called simply a graded vector space without the prefix

\mathbb

, is a vector space together with a decomposition into a direct sum of the form :

V = \bigoplus_ V_n

where each

V_n

is a vector space. For a given ''n'' the elements of

V_n

are then called homogeneous elements of degree ''n''. Graded vector spaces are common. For example the set of all polynomials in one or several variables forms a graded vector space, where the homogeneous elements of degree ''n'' are exactly the linear combinations of monomials of

degree Degree may refer to: As a unit of measurement * Degree (angle), a unit of angle measurement ** Degree of geographical latitude ** Degree of geographical longitude * Degree symbol (°), a notation used in science, engineering, and mathematics ...

''n''.

General gradation

The subspaces of a graded vector space need not be indexed by the set of natural numbers, and may be indexed by the elements of any set ''I''. An ''I''-graded vector space ''V'' is a vector space together with a decomposition into a direct sum of subspaces indexed by elements ''i'' of the set ''I'': :

V = \bigoplus_ V_i.

Therefore, an

\mathbb

-graded vector space, as defined above, is just an ''I''-graded vector space where the set ''I'' is

\mathbb

(the set of natural numbers). The case where ''I'' is the ring

\mathbb/2\mathbb

(the elements 0 and 1) is particularly important in physics. A

(\mathbb/2\mathbb)

-graded vector space is also known as a

supervector space In mathematics, a super vector space is a \mathbb Z_2-graded vector space, that is, a vector space over a field \mathbb K with a given decomposition of subspaces of grade 0 and grade 1. The study of super vector spaces and their generalizations i ...

Homomorphisms

For general index sets ''I'', a linear map between two ''I''-graded vector spaces is called a graded linear map if it preserves the grading of homogeneous elements. A graded linear map is also called a homomorphism (or morphism) of graded vector spaces, or homogeneous linear map: :

f(V_i)\subseteq W_i

for all ''i'' in ''I''. For a fixed field and a fixed index set, the graded vector spaces form a category whose

morphism In mathematics, particularly in category theory, a morphism is a structure-preserving map from one mathematical structure to another one of the same type. The notion of morphism recurs in much of contemporary mathematics. In set theory, morphisms a ...

s are the graded linear maps. When ''I'' is a commutative monoid (such as the natural numbers), then one may more generally define linear maps that are homogeneous of any degree ''i'' in ''I'' by the property :

f(V_j)\subseteq W_

for all ''j'' in ''I'', where "+" denotes the monoid operation. If moreover ''I'' satisfies the cancellation property so that it can be embedded into an abelian group ''A'' that it generates (for instance the integers if ''I'' is the natural numbers), then one may also define linear maps that are homogeneous of degree ''i'' in ''A'' by the same property (but now "+" denotes the group operation in ''A''). Specifically, for ''i'' in ''I'' a linear map will be homogeneous of degree −''i'' if :

f(V_)\subseteq W_j

for all ''j'' in ''I'', while :

f(V_j)=0\,

if is not in ''I''. Just as the set of linear maps from a vector space to itself forms an

associative algebra In mathematics, an associative algebra ''A'' is an algebraic structure with compatible operations of addition, multiplication (assumed to be associative), and a scalar multiplication by elements in some field ''K''. The addition and multiplic ...

(the algebra of endomorphisms of the vector space), the sets of homogeneous linear maps from a space to itself – either restricting degrees to ''I'' or allowing any degrees in the group ''A'' – form associative

graded algebra In mathematics, in particular abstract algebra, a graded ring is a ring such that the underlying additive group is a direct sum of abelian groups R_i such that R_i R_j \subseteq R_. The index set is usually the set of nonnegative integers or the se ...

s over those index sets.

Operations on graded vector spaces

Some operations on vector spaces can be defined for graded vector spaces as well. Given two ''I''-graded vector spaces ''V'' and ''W'', their direct sum has underlying vector space ''V'' ⊕ ''W'' with gradation :(''V'' ⊕ ''W'')_''i'' = ''V_i'' ⊕ ''W_i'' . If ''I'' is a semigroup, then the tensor product of two ''I''-graded vector spaces ''V'' and ''W'' is another ''I''-graded vector space,

V \otimes W

, with gradation :

(V \otimes W)_i = \bigoplus_ V_j \otimes W_k.

Hilbert–Poincaré series

Given a

\N

-graded vector space that is finite-dimensional for every

n\in \N,

its Hilbert–Poincaré series is the

formal power series In mathematics, a formal series is an infinite sum that is considered independently from any notion of convergence, and can be manipulated with the usual algebraic operations on series (addition, subtraction, multiplication, division, partial sum ...

\sum_\dim_K(V_n)\, t^n.

From the formulas above, the Hilbert–Poincaré series of a direct sum and of a tensor product of graded vector spaces (finite dimensional in each degree) are respectively the sum and the product of the corresponding Hilbert–Poincaré series.

References