Relation (mathematics)

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A relation between sets X and Y is a subset of the Cartesian product, ${\displaystyle R\subseteq X\times Y}$. We write ${\displaystyle x~R~y}$ to indicate that ${\displaystyle (x,y)\in R}$, and say that x "stands in the relation R to" y, or that x "is related by R to" y.

The composition of a relation R between X and Y and a relation S between Y and Z is

${\displaystyle R\circ S=\{(x,z)\in X\times Z:\exists y\in Y,~(x,y)\in R{\hbox{ and }}(y,z)\in S\}.\,}$

The transpose of a relation R between X and Y is the relation ${\displaystyle R^{\top }}$ between Y and X defined by

${\displaystyle R^{\top }=\{(y,x)\in Y\times X:(x,y)\in R\}.\,}$

Relations on a set

A relation R on a set X is a relation between X and itself, that is, a subset of ${\displaystyle X\times X}$.

• R is reflexive if ${\displaystyle (x,x)\in R}$ for all ${\displaystyle x\in X}$.
• R is symmetric if ${\displaystyle (x,y)\in R\Leftrightarrow (y,x)\in R}$; that is, ${\displaystyle R=R^{\top }}$.
• R is transitive if ${\displaystyle (x,y),(y,z)\in R\Rightarrow (x,z)}$; that is, ${\displaystyle R\circ R\subseteq R}$.

An equivalence relation is one which is reflexive, symmetric and transitive.

Functions

We say that a relation R is functional if it satisfies the condition that every ${\displaystyle x\in X}$ occurs in exactly one pair ${\displaystyle (x,y)\in R}$. We then define the value of the function at x to be that unique y. We thus identify a function with its graph.