Basis (linear algebra): Difference between revisions

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In [[linear algebra]], a '''basis''' for a [[vector space]] <math>V</math> is a set of [[vector]]s in <math>V</math> such that every vector in <math>V</math> can be written uniquely as a finite [[linear combination]] of vectors in the space.  Every nonzero vector space has a basis, and this fact is the foundation for much of the structure of the theory of vector spaces.  For instance, a basis for a [[finite-dimensional]] vector space provides the space with a [[invertible]] [[linear transformation]] to [[Euclidean space]], given by taking the [[coordinate (mathematics)/advanced|coordinates]] of a vector with respect to a basis.  Through this transformation, every finite dimensional vector space can be considered to be essentially "the same as" a Euclidean space, just with different labels for the vectors and operations.
In [[linear algebra]], a '''basis''' for a [[vector space]] <math>V</math> is a set of [[vector]]s in <math>V</math> such that every vector in <math>V</math> can be written uniquely as a finite [[linear combination]] of vectors in the basis.  One may think of the vectors in a basis as building blocks from which all other vectors in the space can be assembled.  This is similar to viewing the [[prime number]]s as building blocks from which [[positive]] [[integer]]s can be assembled.   
 
Every nonzero vector space has a basis, and in fact, infinitely many different bases.  This result is of paramount importance in the theory of vector spaces, in the same way that the [[unique factorization|unique factorization theorem]] is of fundamental importance in the study of integers.  For instance, the existence of a ''finite'' basis for a vector space provides the space with an [[invertible]] [[linear transformation]] to [[Euclidean space]], given by taking the [[coordinate (mathematics)/advanced|coordinates]] of a vector with respect to a basis.  Through this transformation, every finite dimensional vector space can be considered to be essentially "the same as" the space <math>\mathbb{R}^n</math> just with different labels for the vectors and operations. (Here, <math>\mathbb{R}^n</math> consists of [[row vector]]s <math>(x_1, \ldots, x_n)</math> with <math>n</math> real number entries.)
 
If a vector space has a finite basis, then every basis for the space has the same number of elements: this number is the ''dimension'' of the space.
 
The term '''basis''' is also used in [[abstract algebra]], specifically in the theory of [[free module]]s.  For more on this use of the term, see the [[basis (mathematics)/Advanced|advanced subpage]].
 
==Examples==
* The plane <math>\mathbb{R}^2</math> has a ''standard basis'' often denoted by '''i''' and '''j''', [[unit vector]]s along the ''x'' and ''y'' [[axis|axes]] respectively.  However, there are many other possible bases such as '''i'''+'''j''' and '''i'''-'''j''', or 2'''i'''+3'''j''' and 4'''i'''-5'''j'''.
* The set of solutions to the [[differential equation]] <math>y'' = -y</math> is a vector space with a basis consisting of the two functions <math>y = \sin(x)</math> and <math>y = \cos(x)</math>.  Again there are other possible bases, for example the shifted functions <math>y = \sin(x+\alpha)</math> and <math>y = \cos(x+\alpha)</math> for any [[phase angle]] α.
* The [[polynomial]]s in a variable ''x'' form a vector space.  One basis for this space is the set of all powers ("[[monomial]]s"), <math>1,x,x^2,x^3,\ldots,x^n,\ldots</math>.  Although there are infinitely many elements in this basis, each polynomial can be expressed uniquely as a combination of only finitely many powers: indeed, this is how a polynomial is defined.[[Category:Suggestion Bot Tag]]

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In linear algebra, a basis for a vector space is a set of vectors in such that every vector in can be written uniquely as a finite linear combination of vectors in the basis. One may think of the vectors in a basis as building blocks from which all other vectors in the space can be assembled. This is similar to viewing the prime numbers as building blocks from which positive integers can be assembled.

Every nonzero vector space has a basis, and in fact, infinitely many different bases. This result is of paramount importance in the theory of vector spaces, in the same way that the unique factorization theorem is of fundamental importance in the study of integers. For instance, the existence of a finite basis for a vector space provides the space with an invertible linear transformation to Euclidean space, given by taking the coordinates of a vector with respect to a basis. Through this transformation, every finite dimensional vector space can be considered to be essentially "the same as" the space just with different labels for the vectors and operations. (Here, consists of row vectors with real number entries.)

If a vector space has a finite basis, then every basis for the space has the same number of elements: this number is the dimension of the space.

The term basis is also used in abstract algebra, specifically in the theory of free modules. For more on this use of the term, see the advanced subpage.

Examples

  • The plane has a standard basis often denoted by i and j, unit vectors along the x and y axes respectively. However, there are many other possible bases such as i+j and i-j, or 2i+3j and 4i-5j.
  • The set of solutions to the differential equation is a vector space with a basis consisting of the two functions and . Again there are other possible bases, for example the shifted functions and for any phase angle α.
  • The polynomials in a variable x form a vector space. One basis for this space is the set of all powers ("monomials"), . Although there are infinitely many elements in this basis, each polynomial can be expressed uniquely as a combination of only finitely many powers: indeed, this is how a polynomial is defined.