Equivalence relation - Wiki slovník

Transitive binary relations

	Symmetric	Antisymmetric	Connected	Well-founded	Has joins	Has meets	Reflexive	Irreflexive	Asymmetric
			Total, Semiconnex					Anti- reflexive
Equivalence relation	Y	✗	✗	✗	✗	✗	Y	✗	✗
Preorder (Quasiorder)	✗	✗	✗	✗	✗	✗	Y	✗	✗
Partial order	✗	Y	✗	✗	✗	✗	Y	✗	✗
Total preorder	✗	✗	Y	✗	✗	✗	Y	✗	✗
Total order	✗	Y	Y	✗	✗	✗	Y	✗	✗
Prewellordering	✗	✗	Y	Y	✗	✗	Y	✗	✗
Well-quasi-ordering	✗	✗	✗	Y	✗	✗	Y	✗	✗
Well-ordering	✗	Y	Y	Y	✗	✗	Y	✗	✗
Lattice	✗	Y	✗	✗	Y	Y	Y	✗	✗
Join-semilattice	✗	Y	✗	✗	Y	✗	Y	✗	✗
Meet-semilattice	✗	Y	✗	✗	✗	Y	Y	✗	✗
Strict partial order	✗	✗	✗	✗	✗	✗	✗	Y	Y
Strict weak order	✗	✗	✗	✗	✗	✗	✗	Y	Y
Strict total order	✗	✗	Y	✗	✗	✗	✗	Y	Y
	Symmetric	Antisymmetric	Connected	Well-founded	Has joins	Has meets	Reflexive	Irreflexive	Asymmetric
Definitions, for all $a,b$ and $S\neq \varnothing :$	${\begin{aligned}&aRb\\\Rightarrow {}&bRa\end{aligned}}$	${\begin{aligned}aRb{\text{ and }}&bRa\\\Rightarrow a={}&b\end{aligned}}$	${\begin{aligned}a\neq {}&b\Rightarrow \\aRb{\text{ or }}&bRa\end{aligned}}$	${\begin{aligned}\min S\\{\text{exists}}\end{aligned}}$	${\begin{aligned}a\vee b\\{\text{exists}}\end{aligned}}$	${\begin{aligned}a\wedge b\\{\text{exists}}\end{aligned}}$	$aRa$	${\text{not }}aRa$	${\begin{aligned}aRb\Rightarrow \\{\text{not }}bRa\end{aligned}}$

indicates that the column's property is required by the definition of the row's term (at the very left). For example, the definition of an equivalence relation requires it to be symmetric. ✗ indicates that the property may, or may not hold. All definitions tacitly require the homogeneous relation

R

be transitive: for all

a,b,c,

if

aRb

and

bRc

then

aRc,

and there are additional properties that a homogeneous relation may satisfy.

The 52 equivalence relations on a 5-element set depicted as

5\times 5

logical matrices (colored fields, including those in light gray, stand for ones; white fields for zeros.) The row and column indices of nonwhite cells are the related elements, while the different colors, other than light gray, indicate the equivalence classes (each light gray cell is its own equivalence class).

In mathematics, an equivalence relation is a binary relation that is reflexive, symmetric and transitive. The equipollence relation between line segments in geometry is a common example of an equivalence relation.

Each equivalence relation provides a partition of the underlying set into disjoint equivalence classes. Two elements of the given set are equivalent to each other if and only if they belong to the same equivalence class.

Notation

Various notations are used in the literature to denote that two elements $a$ and $b$ of a set are equivalent with respect to an equivalence relation $R;$ the most common are " $a\sim b$ " and " $a \equiv b$ ", which are used when $R$ is implicit, and variations of " $a\sim _{R}b$ ", " $a \equiv R b$ ", or " ${a\mathop {R} b}$ " to specify $R$ explicitly. Non-equivalence may be written " $a ≁ b$ " or " $a\not \equiv b$ ".

Definition

A binary relation $\,\sim \,$ on a set $X$ is said to be an equivalence relation, if and only if it is reflexive, symmetric and transitive. That is, for all $a,b,$ and $c$ in $X:$

$a\sim a$ (reflexivity).
$a\sim b$ if and only if $b\sim a$ (symmetry).
If $a\sim b$ and $b\sim c$ then $a\sim c$ (transitivity).

$X$ together with the relation $\,\sim \,$ is called a setoid. The equivalence class of $a$ under $\,\sim ,$ denoted $,$ is defined as $=\{x\in X:x\sim a\}.$ ^[1]^[2]

Equivalent definition using algebra of relations

If $R\subseteq X\times Y$ and $S\subseteq Y\times Z$ are relations, then the composite relation $SR\subseteq X\times Z$ is defined so that $x\,SR\,z$ if and only if there is a $y\in Y$ such that $x\,R\,y$ and $y\,S\,z$ .^{[note 1]} This definition is a generalisation of the definition of functional composition. The defining properties of an equivalence relation $R$ on a set $X$ can then be reformulated as follows:

$\operatorname {id} \subseteq R$ . (reflexivity). (Here, $\operatorname {id}$ denotes the identity function on $X$ .)
$R=R^{-1}$ (symmetry).
$RR\subseteq R$ (transitivity).^[3]

Examples

Simple example

On the set $X=\{a,b,c\}$ , the relation $R=\{(a,a),(b,b),(c,c),(b,c),(c,b)\}$ is an equivalence relation. The following sets are equivalence classes of this relation:

=\{a\},~~~~==\{b,c\}.

The set of all equivalence classes for $R$ is $\{\{a\},\{b,c\}\}.$ This set is a partition of the set $X$ with respect to $R$ .

Equivalence relationsedit

The following relations are all equivalence relations:

"Is equal to" on the set of numbers. For example, ${\tfrac {1}{2}}$ is equal to ${\tfrac {4}{8}}.$ ^[2]
"Has the same birthday as" on the set of all people.
"Is similar to" on the set of all triangles.
"Is congruent to" on the set of all triangles.
Given a natural number $n$ , "is congruent to, modulo $n$ " on the integers.^[2]
Given a function $f:X\to Y$ , "has the same image under $f$ as" on the elements of $f$ 's domain $X$ . For example, $0$ and $\pi$ have the same image under $\sin$ , viz. $0$ .
"Has the same absolute value as" on the set of real numbers
"Has the same cosine as" on the set of all angles.

Relations that are not equivalencesedit

The relation "≥" between real numbers is reflexive and transitive, but not symmetric. For example, 7 ≥ 5 but not 5 ≥ 7.
The relation "has a common factor greater than 1 with" between natural numbers greater than 1, is reflexive and symmetric, but not transitive. For example, the natural numbers 2 and 6 have a common factor greater than 1, and 6 and 3 have a common factor greater than 1, but 2 and 3 do not have a common factor greater than 1.
The empty relation R (defined so that aRb is never true) on a set X is vacuously symmetric and transitive; however, it is not reflexive (unless X itself is empty).
The relation "is approximately equal to" between real numbers, even if more precisely defined, is not an equivalence relation, because although reflexive and symmetric, it is not transitive, since multiple small changes can accumulate to become a big change. However, if the approximation is defined asymptotically, for example by saying that two functions f and g are approximately equal near some point if the limit of f − g is 0 at that point, then this defines an equivalence relation.

Connections to other relationsedit

A partial order is a relation that is reflexive, antisymmetric, and transitive.
Equality is both an equivalence relation and a partial order. Equality is also the only relation on a set that is reflexive, symmetric and antisymmetric. In algebraic expressions, equal variables may be substituted for one another, a facility that is not available for equivalence related variables. The equivalence classes of an equivalence relation can substitute for one another, but not individuals within a class.
A strict partial order is irreflexive, transitive, and asymmetric.
A partial equivalence relation is transitive and symmetric. Such a relation is reflexive if and only if it is total, that is, if for all $a,$ there exists some $b{\text{ such that }}a\sim b.$ ^{[proof 1]} Therefore, an equivalence relation may be alternatively defined as a symmetric, transitive, and total relation.
A ternary equivalence relation is a ternary analogue to the usual (binary) equivalence relation.
A reflexive and symmetric relation is a dependency relation (if finite), and a tolerance relation if infinite.
A preorder is reflexive and transitive.
A congruence relation is an equivalence relation whose domain $X$ is also the underlying set for an algebraic structure, and which respects the additional structure. In general, congruence relations play the role of kernels of homomorphisms, and the quotient of a structure by a congruence relation can be formed. In many important cases, congruence relations have an alternative representation as substructures of the structure on which they are defined (e.g., the congruence relations on groups correspond to the normal subgroups).
Any equivalence relation is the negation of an apartness relation, though the converse statement only holds in classical mathematics (as opposed to constructive mathematics), since it is equivalent to the law of excluded middle.
Each relation that is both reflexive and left (or right) Euclidean is also an equivalence relation.

Well-definedness under an equivalence relationedit

If $\,\sim \,$ is an equivalence relation on $X,$ and $P(x)$ is a property of elements of $X,$ such that whenever $x\sim y,$ $P(x)$ is true if $P(y)$ is true, then the property $P$ is said to be well-defined or a class invariant under the relation $\,\sim .$

A frequent particular case occurs when $f$ is a function from $X$ to another set $Y;$

[1]

[2]

[note 1]

[3]

[proof 1]