Difference between revisions of "Equivalence relation"
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Let $X$ be a set. An equivalence relation on $X$ is a subset $R\subseteq X\times X$ that satisfies the following three properties: | Let $X$ be a set. An equivalence relation on $X$ is a subset $R\subseteq X\times X$ that satisfies the following three properties: | ||
− | 1) Reflexivity: for all $x\in X$, $(x,x)\in R$; | + | 1) [[Reflexivity]]: for all $x\in X$, $(x,x)\in R$; |
− | 2) Symmetry: for all $x,y\in X$, if $(x,y)\in R$ then $(y,x)\in R$; | + | 2) [[Symmetry (of a relation)|Symmetry]]: for all $x,y\in X$, if $(x,y)\in R$ then $(y,x)\in R$; |
− | 3) Transitivity: for all $x,y,z \in X$, if $(x,y)\in R$ and $(y,z)\in R$ then $(x,z)\in R$. | + | 3) [[Transitivity]]: for all $x,y,z \in X$, if $(x,y)\in R$ and $(y,z)\in R$ then $(x,z)\in R$. |
When $(x,y)\in R$ we say that $x$ is equivalent to $y$. | When $(x,y)\in R$ we say that $x$ is equivalent to $y$. |
Revision as of 19:41, 12 October 2014
2020 Mathematics Subject Classification: Primary: 03E [MSN][ZBL]
Let $X$ be a set. An equivalence relation on $X$ is a subset $R\subseteq X\times X$ that satisfies the following three properties:
1) Reflexivity: for all $x\in X$, $(x,x)\in R$;
2) Symmetry: for all $x,y\in X$, if $(x,y)\in R$ then $(y,x)\in R$;
3) Transitivity: for all $x,y,z \in X$, if $(x,y)\in R$ and $(y,z)\in R$ then $(x,z)\in R$.
When $(x,y)\in R$ we say that $x$ is equivalent to $y$.
Instead of $(x,y)\in R$, the notation $xRy$, or even $x\sim y$, is also used.
An equivalence relation is a binary relation.
Example: If $f$ maps the set $X$ into a set $Y$, then $R=\{(x_1,x_2)\in X\times X\,:\, f(x_1)=f(x_2)\}$ is an equivalence relation.
For any $y\in X$ the subset of $X$ that consists of all $x$ that are equivalent to $y$ is called the equivalence class of $y$. Any two equivalence classes either are disjoint or coincide, that is, any equivalence relation on $X$ defines a partition (decomposition) of $X$, and vice versa.
Equivalence relation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Equivalence_relation&oldid=33589