Difference between revisions of "Functional relation"

Latest revision as of 07:00, 1 May 2016

2020 Mathematics Subject Classification: Primary: 03-XX [MSN][ZBL]

A binary relation $R$ on a set $A$ satisfying $R^{-1}\circ R\subseteq\Delta$ , where $R^{-1}$ is the transposed relation, $\Delta$ is the diagonal of $A$ and $\circ$ denotes composition. This means that $(a,b)\in R$ and $(a,c)\in R$ imply that $b=c$ , that is, for each $a\in A$ there is at most one $b\in A$ such that $(a,b)\in R$ . Thus, $R$ determines a function (perhaps not defined everywhere) on $A$ . When it satisfies $R^{-1}\circ R=\Delta$ this function is well-defined everywhere and is one-to-one.

Comments

A functional relation is more generally defined as a binary relation $R\subset A\times B$ between sets $A$ and $B$ such that $(a,b)\in R$ and $(a,c)\in R$ imply $b=c$ .

How to Cite This Entry:
Functional relation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Functional_relation&oldid=31682

This article was adapted from an original article by O.A. Ivanova (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article

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-A [[Binary relation|binary relation]]  $R$  on a set  $A$  satisfying  $R^{-1}\circ R\subseteq\Delta$ , where  $\Delta$  is the diagonal of  $A$ . This means that  $(a,b)\in R$  and  $(a,c)\in R$  imply that  $b=c$ , that is, for each  $a\in A$  there is at most one  $b\in A$  such that  $(a,b)\in R$ . Thus,  $R$  determines a function (perhaps not defined everywhere) on  $A$ . When it satisfies  $R^{-1}\circ R=\Delta$  this function is well-defined everywhere and is one-to-one.
+A [[binary relation]]  $R$  on a set  $A$  satisfying  $R^{-1}\circ R\subseteq\Delta$ , where  $R^{-1}$  is the [[transposed relation]],  $\Delta$  is the diagonal of  $A$  and  $\circ$  denotes [[composition]]. This means that  $(a,b)\in R$  and  $(a,c)\in R$  imply that  $b=c$ , that is, for each  $a\in A$  there is at most one  $b\in A$  such that  $(a,b)\in R$ . Thus,  $R$  determines a function (perhaps not defined everywhere) on  $A$ . When it satisfies  $R^{-1}\circ R=\Delta$  this function is well-defined everywhere and is one-to-one.

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Difference between revisions of "Functional relation"

Latest revision as of 07:00, 1 May 2016

Comments