Hexagonal number: Difference between revisions

Revision as of 19:49, 29 December 2013

Template:Otheruses4 In mathematics, especially in the area of abstract algebra known as ring theory, a free algebra is the noncommutative analogue of a polynomial ring (which may be regarded as a free commutative algebra).

Definition

For R a commutative ring, the free (associative, unital) algebra on n indeterminates {X₁,...,X_n} is the free R-module with a basis consisting of all words over the alphabet {X₁,...,X_n} (including the empty word, which is the unity of the free algebra). This R-module becomes an R-algebra by defining a multiplication as follows: the product of two basis elements is the concatenation of the corresponding words:

(X_{i_{1}} X_{i_{2}} \dots X_{i_{m}}) \cdot (X_{j_{1}} X_{j_{2}} \dots X_{j_{n}}) = X_{i_{1}} X_{i_{2}} \dots X_{i_{m}} X_{j_{1}} X_{j_{2}} \dots X_{j_{n}},

and the product of two arbitrary elements is thus uniquely determined (because the multiplication in an R-algebra must be R-bilinear). This R-algebra is denoted R⟨X₁,...,X_n⟩. This construction can easily be generalized to an arbitrary set X of indeterminates.

In short, for an arbitrary set $X = {X_{i}; i \in I}$ , the free (associative, unital) R-algebra on X is

R ⟨ X ⟩ : = ⨁_{w \in X^{*}} R w

with the R-bilinear multiplication that is concatenation on words, where X* denotes the free monoid on X (i.e. words on the letters X_i), $\oplus$ denotes the external direct sum, and Rw denotes the free R-module on 1 element, the word w.

For example, in R⟨X₁,X₂,X₃,X₄⟩, for scalars α,β,γ,δ ∈R, a concrete example of a product of two elements is $(α X_{1} X_{2}^{2} + β X_{2} X_{3}) \cdot (γ X_{2} X_{1} + δ X_{1}^{4} X_{4}) = α γ X_{1} X_{2}^{3} X_{1} + α δ X_{1} X_{2}^{2} X_{1}^{4} X_{4} + β γ X_{2} X_{3} X_{2} X_{1} + β δ X_{2} X_{3} X_{1}^{4} X_{4}$ .

The non-commutative polynomial ring may be identified with the monoid ring over R of the free monoid of all finite words in the X_i.

Contrast with Polynomials

Since the words over the alphabet {X₁, ...,X_n} form a basis of R⟨X₁,...,X_n⟩, it is clear that any element of R⟨X₁, ...,X_n⟩ can be uniquely written in the form:

\sum_{i_{1}, i_{2}, \dots, i_{k} \in {1, 2, \dots, n}} a_{i_{1}, i_{2}, \dots, i_{k}} X_{i_{1}} X_{i_{2}} \dots X_{i_{k}},

where $a_{i_{1}, i_{2}, . . ., i_{k}}$ are elements of R and all but finitely many of these elements are zero. This explains why the elements of R⟨X₁,...,X_n⟩ are often denoted as "non-commutative polynomials" in the "variables" (or "indeterminates") X₁,...,X_n; the elements $a_{i_{1}, i_{2}, . . ., i_{k}}$ are said to be "coefficients" of these polynomials, and the R-algebra R⟨X₁,...,X_n⟩ is called the "non-commutative polynomial algebra over R in n indeterminates". Note that unlike in an actual polynomial ring, the variables do not commute. For example X₁X₂ does not equal X₂X₁.

More generally, one can construct the free algebra R⟨E⟩ on any set E of generators. Since rings may be regarded as Z-algebras, a free ring on E can be defined as the free algebra Z⟨E⟩.

Over a field, the free algebra on n indeterminates can be constructed as the tensor algebra on an n-dimensional vector space. For a more general coefficient ring, the same construction works if we take the free module on n generators.

The construction of the free algebra on E is functorial in nature and satisfies an appropriate universal property. The free algebra functor is left adjoint to the forgetful functor from the category of R-algebras to the category of sets.

Free algebras over division rings are free ideal rings.

References

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+{{Otheruses4|free algebras in ring theory|the more general free algebras in [[universal algebra]]|free object}}
+In [[mathematics]], especially in the area of [[abstract algebra]] known as [[ring theory]], a '''free algebra''' is the noncommutative analogue of a [[polynomial ring]] (which may be regarded as a '''free commutative algebra''').
+==Definition==
+For ''R'' a [[commutative ring]], the free ([[associative]], [[unital algebra|unital]]) [[algebra (ring theory)|algebra]] on ''n'' [[indeterminate_(variable)|indeterminate]]s {''X''<sub>1</sub>,...,''X<sub>n</sub>''} is the [[free module|free ''R''-module]] with a basis consisting of all [[Word_(mathematics)|words]] over the alphabet {''X''<sub>1</sub>,...,''X<sub>n</sub>''} (including the empty word, which is the unity of the free algebra). This ''R''-module becomes an [[algebra (ring theory)|''R''-algebra]] by defining a multiplication as follows: the product of two basis elements is the [[concatenation]] of the corresponding words:
+:<math>\left(X_{i_1}X_{i_2} \cdots X_{i_m}\right) \cdot \left(X_{j_1}X_{j_2} \cdots X_{j_n}\right) = X_{i_1}X_{i_2} \cdots X_{i_m}X_{j_1}X_{j_2} \cdots X_{j_n},</math>
+and the product of two arbitrary elements is thus uniquely determined (because the multiplication in an ''R''-algebra must be ''R''-bilinear). This ''R''-algebra is denoted ''R''⟨''X''<sub>1</sub>,...,''X<sub>n</sub>''⟩. This construction can easily be generalized to an arbitrary set ''X'' of indeterminates.
+In short, for an arbitrary set <math>X=\{X_i\,;\; i\in I\}</math>, the '''free ([[associative]], [[unital algebra|unital]]) ''R''-[[algebra (ring theory)|algebra]] on ''X''''' is
+:<math>R\langle X\rangle:=\bigoplus_{w\in X^\ast}R w</math>
+with the ''R''-bilinear multiplication that is concatenation on words, where ''X''* denotes the [[free monoid]] on ''X'' (i.e. words on the letters ''X''<sub>i</sub>), <math>\oplus</math> denotes the external [[Direct sum of modules|direct sum]], and ''Rw'' denotes the [[free module|free ''R''-module]] on 1 element, the word ''w''.
+For example, in ''R''⟨''X''<sub>1</sub>,''X''<sub>2</sub>,''X''<sub>3</sub>,''X''<sub>4</sub>⟩, for scalars ''α,β,γ,δ'' ∈''R'', a concrete example of a product of two elements is <math>(\alpha X_1X_2^2 + \beta X_2X_3)\cdot(\gamma X_2X_1 + \delta X_1^4X_4) = \alpha\gamma X_1X_2^3X_1 + \alpha\delta X_1X_2^2X_1^4X_4 + \beta\gamma X_2X_3X_2X_1 + \beta\delta X_2X_3X_1^4X_4</math>.
+The non-commutative polynomial ring may be identified with the [[monoid ring]] over ''R'' of the [[free monoid]] of all finite words in the ''X''<sub>''i''</sub>.
+==Contrast with Polynomials==
+Since the words over the alphabet {''X''<sub>1</sub>, ...,''X<sub>n</sub>''} form a basis of ''R''⟨''X''<sub>1</sub>,...,''X<sub>n</sub>''⟩, it is clear that any element of ''R''⟨''X''<sub>1</sub>, ...,''X<sub>n</sub>''⟩ can be uniquely written in the form:
+:<math>\sum\limits_{i_1,i_2, \cdots ,i_k\in\left\lbrace 1,2, \cdots ,n\right\rbrace} a_{i_1,i_2, \cdots ,i_k} X_{i_1} X_{i_2} \cdots X_{i_k},</math>
+where <math>a_{i_1,i_2,...,i_k}</math> are elements of ''R'' and all but finitely many of these elements are zero. This explains why the elements of ''R''⟨''X''<sub>1</sub>,...,''X<sub>n</sub>''⟩ are often denoted as "non-commutative polynomials" in the "variables" (or "indeterminates") ''X''<sub>1</sub>,...,''X<sub>n</sub>''; the elements <math> a_{i_1,i_2,...,i_k}</math> are said to be "coefficients" of these polynomials, and the ''R''-algebra ''R''⟨''X''<sub>1</sub>,...,''X<sub>n</sub>''⟩ is called the "non-commutative polynomial algebra over ''R'' in ''n'' indeterminates". Note that unlike in an actual polynomial ring, the variables do not [[commutative operation|commute]]. For example ''X''<sub>1</sub>''X''<sub>2</sub> does not equal ''X''<sub>2</sub>''X''<sub>1</sub>.
+More generally, one can construct the free algebra ''R''⟨''E''⟩ on any set ''E'' of [[generating set|generators]]. Since rings may be regarded as '''Z'''-algebras, a '''free ring''' on ''E'' can be defined as the free algebra '''Z'''⟨''E''⟩.
+Over a [[field (mathematics)|field]], the free algebra on ''n'' indeterminates can be constructed as the [[tensor algebra]] on an ''n''-dimensional [[vector space]].  For a more general coefficient ring, the same construction works if we take the [[free module]] on ''n'' [[generating set|generators]].
+The construction of the free algebra on ''E'' is [[functor]]ial in nature and satisfies an appropriate [[universal property]]. The free algebra functor is [[left adjoint]] to the [[forgetful functor]] from the category of ''R''-algebras to the [[category of sets]].
+Free algebras over [[division ring]]s are [[free ideal ring]]s.
+==See also==
+*[[Cofree coalgebra]]
+*[[Tensor algebra]]
+*[[Free object]]
+*[[Noncommutative ring]]
+==References==
+* {{cite book | last1=Berstel | first1=Jean | last2=Reutenauer | first2=Christophe | title=Noncommutative rational series with applications | series=Encyclopedia of Mathematics and Its Applications | volume=137 | location=Cambridge | publisher=[[Cambridge University Press]] | year=2011 | isbn=978-0-521-19022-0 | zbl=1250.68007 }}
+* {{springer|id=f/f041520|author=L.A. Bokut'|title=Free associative algebra}}
+[[Category:Algebras]]
+[[Category:Ring theory]]
+[[Category:Free algebraic structures]]

Hexagonal number: Difference between revisions

Revision as of 19:49, 29 December 2013

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Definition

Contrast with Polynomials

See also

References

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Hexagonal number: Difference between revisions

Revision as of 19:49, 29 December 2013

Definition

Contrast with Polynomials

See also

References

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