Relations

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updates: 1 July 2011

Definitions

Let $S$ be a set.

A relation on $S$ is a subset of $S \times S$ . Write $s_{1} \sim s_{2}$ if the pair $(s_{1}, s_{2})$ is in the subset.
A relation $\sim$ on $S$ is reflexive if $\sim$ satisfies $if s \in S then s \sim s .$
A relation $\sim$ on $S$ is symmetric if $\sim$ satisfies $if s_{1}, s_{2} \in S and s_{1} \sim s_{2} then s_{2} \sim s_{1} .$
A relation $\sim$ on $S$ is transitive if $\sim$ satisfies $if s_{1}, s_{2}, s_{3} \in S and s_{1} \sim s_{2} and s_{2} \sim s_{3} then s_{1} \sim s_{3} .$
An equivalence relation on $S$ is a relation on $S$ that is reflexive, symmetric and transitive.

Examples. Let $S$ be the set ${1, 2, 6}$ .

(a)

R_{1} = {(1, 1), (2, 6), (6, 1)}

is a relation on

S

(b)

R_{1}

is not reflexive, not symmetric and not transitive.

(c)

R_{2} = {(1, 1), (2, 6), (6, 1), (2, 1)}

is a relation on

S

(d)

R_{2}

is transitive but not reflexive and not symmetric.

Let $S$ be a set.

Let $\sim$ be an equivalence relation on $S$ and let $s \in S$ . The equivalence class of $s$ is the set $[s] = {t \in S | t \sim s} .$
A partition of a set $S$ is a collection of subsets $S_{α}$ such that

(a) if $s \in S$ then there exists $α$ such that $s \in S_{α}$ , and

(b) if $S_{α} \cap S_{β} \neq \emptyset$ then $S_{α} = S_{β}$ .

(a) Let

S

be a set and let

\sim

be an equivalence relation on

S

Then the set of equivalence classes of the relation

\sim

is a partition of

S

(b) Let

S

be a set and let

{S_{α}}

be a partition of

S

Then the relation defined by

s \sim t if s and t are in the same S_{α}

is an equivalence relation on

S

Proposition (eqrelptn) shows that the concepts of an equivalence relation on $S$ and of a partition on $S are essentially the same. Each equivalence relation on S determines a partition and vice versa.$

Example. Let $S = {1, 2, 3, \dots, 10}$ . Let $\sim$ be the equivalence relation determined by

$1 \sim 5$ ,	$2 \sim 3$ ,	$9 \sim 10$ ,
$1 \sim 7$ ,	$5 \sim 8$ ,	$10 \sim 4$ ,

Since we are requiring that

\sim

is an equivalence relation, we are assuming that we have all the other relations we need such that

\sim

is reflexive, symmetric and transitive;

$1 \sim 1$ ,	$2 \sim 2$ ,	…	$9 \sim 9$ ,	$10 \sim 10$ ,
$5 \sim 7$ ,	$7 \sim 8$ ,	$7 \sim 5$ ,	$5 \sim 1$ ,	…

The equivalence classes are given by

\begin{array}{rcl} [1] = [5] = [7] = [8] & = & {1, 5, 7, 8}, \\ [2] = [3] & = & {2, 3}, \\ [6] & = & {6}, and \\ [4] = [9] = [10] & = & {4, 9, 10}, \end{array}

and the sets

S_{1} = {1, 5, 7, 8}, S_{2} = {2, 3}, S_{3} = {6}, and S_{4} = {4, 9, 10}

form a partition of

S

Notes and References

These notes are an updated version of notes of Arun Ram from 1994.

References

[Ram] A. Ram, Notes in abstract algebra, University of Wisconsin, Madison 1993-1994.

[Bou] N. Bourbaki, Algèbre, Chapitre 9: Formes sesquilinéaires et formes quadratiques, Actualités Sci. Ind. no. 1272 Hermann, Paris, 1959, 211 pp. MR0107661.

[Ru] W. Rudin, Real and complex analysis, Third edition, McGraw-Hill, 1987. MR0924157.

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