Antisymmetric relation

Last updated January 25, 2024

	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	Y
Strict weak order	✗	Y	✗	✗	✗	✗	✗	Y	Y
Strict total order	✗	Y	Y	✗	✗	✗	✗	Y	Y
	Symmetric	Antisymmetric	Connected	Well-founded	Has joins	Has meets	Reflexive	Irreflexive	Asymmetric
Definitions, for all $a,b$ and ${\displaystyle S\neq \varnothing$	${\begin{aligned}&aRb\\\Rightarrow {}&bRa\end{aligned}}$	${\begin{aligned}aRb{\text{ and }}&bRa\\\Rightarrow a={}&b\end{aligned}}$	${\begin{aligned}a\neq {}&b\Rightarrow \\aRb{\text{ or }}&bRa\end{aligned}}$	${\begin{aligned}\min S\\{\text{exists}}\end{aligned}}$	${\begin{aligned}a\vee b\\{\text{exists}}\end{aligned}}$	${\begin{aligned}a\wedge b\\{\text{exists}}\end{aligned}}$	$aRa$	${\text{not }}aRa$	${\begin{aligned}aRb\Rightarrow \\{\text{not }}bRa\end{aligned}}$

indicates that the column's property is always true the row's term (at the very left), while ✗ indicates that the property is not guaranteed in general (it might, or might not, hold). For example, that every equivalence relation is symmetric, but not necessarily antisymmetric, is indicated by

in the "Symmetric" column and ✗ in the "Antisymmetric" column, respectively.

All definitions tacitly require the homogeneous relation $R$ be transitive: for all $a,b,c,$ if $aRb$ and $bRc$ then $aRc.$
A term's definition may require additional properties that are not listed in this table.

The definition of antisymmetry says nothing about whether $aRa$ actually holds or not for any $a$ . An antisymmetric relation $R$ on a set $X$ may be reflexive (that is, $aRa$ for all $a\in X$ ), irreflexive (that is, $aRa$ for no $a\in X$ ), or neither reflexive nor irreflexive. A relation is asymmetric if and only if it is both antisymmetric and irreflexive.

Examples

The divisibility relation on the natural numbers is an important example of an antisymmetric relation. In this context, antisymmetry means that the only way each of two numbers can be divisible by the other is if the two are, in fact, the same number; equivalently, if $n$ and $m$ are distinct and $n$ is a factor of $m,$ then $m$ cannot be a factor of $n.$ For example, 12 is divisible by 4, but 4 is not divisible by 12.

The usual order relation $\,\leq \,$ on the real numbers is antisymmetric: if for two real numbers $x$ and $y$ both inequalities $x\leq y$ and $y\leq x$ hold, then $x$ and $y$ must be equal. Similarly, the subset order $\,\subseteq \,$ on the subsets of any given set is antisymmetric: given two sets $A$ and $B,$ if every element in $A$ also is in $B$ and every element in $B$ is also in $A,$ then $A$ and $B$ must contain all the same elements and therefore be equal:

A\subseteq B{\text{ and }}B\subseteq A{\text{ implies }}A=B

A real-life example of a relation that is typically antisymmetric is "paid the restaurant bill of" (understood as restricted to a given occasion). Typically, some people pay their own bills, while others pay for their spouses or friends. As long as no two people pay each other's bills, the relation is antisymmetric.

Properties

Symmetric and antisymmetric relations Symmetric-and-or-antisymmetric.svg — Symmetric and antisymmetric relations

Partial and total orders are antisymmetric by definition. A relation can be both symmetric and antisymmetric (in this case, it must be coreflexive), and there are relations which are neither symmetric nor antisymmetric (for example, the "preys on" relation on biological species).

Antisymmetry is different from asymmetry: a relation is asymmetric if and only if it is antisymmetric and irreflexive.

Related Research Articles

In mathematics, a binary relation associates elements of one set, called the domain, with elements of another set, called the codomain. A binary relation over sets $X$ and $Y$ is a new set of ordered pairs $(x, y)$ consisting of elements $x$ from $X$ and $y$ from $Y$ . It is a generalization of the more widely understood idea of a unary function. It encodes the common concept of relation: an element $x$ is related to an element $y$ , if and only if the pair $(x, y)$ belongs to the set of ordered pairs that defines the binary relation. A binary relation is the most studied special case $n = 2$ of an $n$ -ary relation over sets $X 1, ..., X n$ , which is a subset of the Cartesian product

In mathematics, a directed set is a nonempty set $together with a reflexive and transitive binary relation, with the additional property that every pair of elements has an upper bound. In other words, for any and in there must exist in with and A directed set's preorder is called a direction .$

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. A simpler example is equality. Any number $is equal to itself (reflexive). If, then (symmetric). If and, then (transitive).$

In mathematics, especially order theory, a partial order on a set is an arrangement such that, for certain pairs of elements, one precedes the other. The word partial is used to indicate that not every pair of elements needs to be comparable; that is, there may be pairs for which neither element precedes the other. Partial orders thus generalize total orders, in which every pair is comparable.

In mathematics, especially in order theory, a preorder or quasiorder is a binary relation that is reflexive and transitive. Preorders are more general than equivalence relations and (non-strict) partial orders, both of which are special cases of a preorder: an antisymmetric preorder is a partial order, and a symmetric preorder is an equivalence relation.

In mathematics, a set A is a subset of a set B if all elements of A are also elements of B; B is then a superset of A. It is possible for A and B to be equal; if they are unequal, then A is a proper subset of B. The relationship of one set being a subset of another is called inclusion. A is a subset of B may also be expressed as B includes A or A is included in B. A k-subset is a subset with k elements.

In mathematics, a total order or linear order is a partial order in which any two elements are comparable. That is, a total order is a binary relation $on some set, which satisfies the following for all and in :$

$(reflexive).$
If $and then (transitive).$
If $and then (antisymmetric).$
$or .$

In mathematics, a binary relation $on a set is reflexive if it relates every element of to itself.$

In mathematics, a binary relation $R$ on a set $X$ is transitive if, for all elements $a$ , $b$ , $c$ in $X$ , whenever $R$ relates $a$ to $b$ and $b$ to $c$ , then $R$ also relates $a$ to $c$ .

In mathematics, especially in order theory, a maximal element of a subset $of some preordered set is an element of that is not smaller than any other element in . A minimal element of a subset of some preordered set is defined dually as an element of that is not greater than any other element in .$

This is a glossary of some terms used in various branches of mathematics that are related to the fields of order, lattice, and domain theory. Note that there is a structured list of order topics available as well. Other helpful resources might be the following overview articles:

In mathematics, especially in order theory, the greatest element of a subset $of a partially ordered set (poset) is an element of that is greater than every other element of . The term least element is defined dually, that is, it is an element of that is smaller than every other element of$

In mathematics, specifically order theory, a well-quasi-ordering or wqo on a set $is a quasi-ordering of for which every infinite sequence of elements from contains an increasing pair with$

<span class="mw-page-title-main">Weak ordering</span> Mathematical ranking of a set

In mathematics, especially order theory, a weak ordering is a mathematical formalization of the intuitive notion of a ranking of a set, some of whose members may be tied with each other. Weak orders are a generalization of totally ordered sets and are in turn generalized by (strictly) partially ordered sets and preorders.

In mathematics, an asymmetric relation is a binary relation $on a set where for all if is related to then is not related to$

In mathematics, a subset $of a preordered set is said to be cofinal or frequent in if for every it is possible to find an element in that is "larger than ".$

In set theory, a prewellordering on a set $is a preorder on that is strongly connected and well-founded in the sense that the induced relation defined by is a well-founded relation.$

In mathematics, Euclidean relations are a class of binary relations that formalize "Axiom 1" in Euclid's Elements: "Magnitudes which are equal to the same are equal to each other."

In mathematics, a homogeneous relation on a set X is a binary relation between X and itself, i.e. it is a subset of the Cartesian product $X \times X$ . This is commonly phrased as "a relation on X" or "a (binary) relation over X". An example of a homogeneous relation is the relation of kinship, where the relation is between people.

In mathematics, a relation on a set may, or may not, hold between two given members of the set. As an example, "is less than" is a relation on the set of natural numbers; it holds, for instance, between the values $1$ and $3$ , and likewise between $3$ and $4$ , but not between the values $3$ and $1$ nor between $4$ and $4$ , that is, $3 < 1$ and $4 < 4$ both evaluate to false. As another example, "is sister of" is a relation on the set of all people, it holds e.g. between Marie Curie and Bronisława Dłuska, and likewise vice versa. Set members may not be in relation "to a certain degree" – either they are in relation or they are not.

References

Weisstein, Eric W. "Antisymmetric Relation". MathWorld .
Lipschutz, Seymour; Marc Lars Lipson (1997). Theory and Problems of Discrete Mathematics . McGraw-Hill. p. 33. ISBN 0-07-038045-7.
nLab antisymmetric relation

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Antisymmetric relation

Contents

Examples

Properties

See also

Related Research Articles

References