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• Bijective function
  ...t each element of one set has its unique counterpart in the second set. A bijective function from a set X to itself is also called a '''permutation''' of the set X. The most important property of a bijective function is the existence of an [[inverse function]] which ''undoes'' the operation
  4 KB (618 words) - 22:24, 7 February 2010
• Bijective function/Definition
  122 bytes (17 words) - 13:14, 13 November 2008
• Bijective function/Related Articles
  907 bytes (142 words) - 14:42, 2 November 2008

Page text matches

• One-to-one correspondence
  #REDIRECT [[Bijective function]]
  32 bytes (3 words) - 12:38, 2 November 2008
• Bijection
  #REDIRECT [[Bijective function]]
  32 bytes (3 words) - 12:38, 2 November 2008
• Inverse function
  ...first. Not every function has an inverse, and those that do are called [[bijective function|invertible]] (or bijective).
  1 KB (173 words) - 20:09, 27 November 2008
• Homeomorphism
  ...t maps one [[topological space]] to another with the property that it is [[bijective function|bijective]] and both the function and its [[inverse function|inverse]] are #f is a bijective function (i.e., it is [[injective function|one-to-one]] and [[surjective function|on
  2 KB (265 words) - 07:44, 4 January 2009
• Bijective function
  ...t each element of one set has its unique counterpart in the second set. A bijective function from a set X to itself is also called a '''permutation''' of the set X. The most important property of a bijective function is the existence of an [[inverse function]] which ''undoes'' the operation
  4 KB (618 words) - 22:24, 7 February 2010
• Surjective function
  * [[Bijective function]]
  710 bytes (120 words) - 13:08, 13 November 2008
• Inverse function/Related Articles
  {{r|Bijective function}}
  739 bytes (92 words) - 17:31, 11 January 2010
• Injective function
  * [[Bijective function]]
  894 bytes (148 words) - 12:23, 13 November 2008
• Calculus/Related Articles
  {{r|Bijective function}}
  1 KB (136 words) - 11:36, 11 January 2010
• Identity function/Related Articles
  {{r|Bijective function}}
  568 bytes (70 words) - 17:23, 11 January 2010
• Cardinal number/Related Articles
  {{r|Bijective function}}
  370 bytes (47 words) - 17:50, 26 June 2009
• Surjective function/Related Articles
  {{r|Bijective function}}
  906 bytes (142 words) - 13:12, 13 November 2008
• Injective function/Related Articles
  {{r|Bijective function}}
  907 bytes (142 words) - 13:06, 13 November 2008
• Function (mathematics)/Related Articles
  {{r|Bijective function}}
  1 KB (172 words) - 15:25, 15 May 2011
• Conjugation (group theory)
  Since <math>T_y</math> is thus a [[bijective function]], with [[inverse function]] <math>T_{y^{-1}}</math>, it is an [[automorph
  2 KB (294 words) - 04:53, 19 November 2008
• Integer/Related Articles
  {{r|Bijective function}}
  2 KB (247 words) - 17:28, 11 January 2010
• Schröder-Bernstein theorem
  then there is a bijective function from ''A'' onto ''B''. The bijective function between the two sets can be explicitly constructed from the two injective f
  8 KB (1,281 words) - 15:39, 23 September 2013
• Schröder-Bernstein theorem/Citable Version
  then there is a bijective function from ''A'' onto ''B''. The bijective function between the two sets can be explicitly constructed from the two injective f
  8 KB (1,275 words) - 15:34, 23 September 2013
• Galileo's paradox
  ...f the other. (This is an early use, though not the first, of a proof by [[bijective function|one-to-one correspondence]] of infinite sets.)
  1 KB (198 words) - 01:29, 12 July 2008
• Field automorphism
  ...e [[algebraic structure]] of a [[field (mathematics)|field]], that is, a [[bijective function]] from the field onto itself which respects the fields operations of additi
  3 KB (418 words) - 12:18, 20 December 2008
• Aleph-0
  a [[bijective function|one-to-one correspondence]] between all elements of the set and all natural
  1 KB (214 words) - 13:35, 6 July 2009
• Manifold (geometry)
  ...<math>\scriptstyle \mathbb{R}^n </math> (i.e. there exists a continuous [[bijective function]] from the said neighborhood, with a continuous inverse, to <math>\scriptst
  5 KB (805 words) - 17:01, 28 November 2008
• Group (mathematics)/Catalogs
  Many examples of groups come from considering some object and a set of [[bijective function]]s from the object to itself, which preserve some structure that this objec
  5 KB (819 words) - 10:52, 15 September 2009
• Group theory
  ...re ''isomorphic'' if there is a [[surjective function|surjective]] (thus [[bijective function|bijective]]) embedding of one into the other (then the embedding is called
  15 KB (2,535 words) - 20:29, 14 February 2010
• Function (mathematics)
  * A [[bijective function]] is one which is both surjective and injective.
  15 KB (2,342 words) - 06:26, 30 November 2011
• Schröder-Bernstein property/Citable Version
  * "similar" is interpreted as [[Bijective function#Bijections and the concept of cardinality|equinumerous]].
  6 KB (944 words) - 15:09, 23 September 2013
• Schröder-Bernstein property
  * "similar" is interpreted as [[Bijective function#Bijections and the concept of cardinality|equinumerous]].
  6 KB (944 words) - 08:32, 14 October 2013
• Set (mathematics)
  *A [[bijective function]] (or '''invertible function''') is one which is both surjective and inject
  17 KB (2,828 words) - 10:37, 24 July 2011