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 Definition

A binary endorelation $R$ on a set $A$ is dense if for all $x \in A$ and $y \in A$ such that $R(x, y)$ there exists an element $z \in A$ such that $R(x, z)$ and $R(z, y)$. Equivalently, a binary relation $R$ on $A$ is dense if $R$ is a subset of the composite $R \circ R$ in Rel, $R \subseteq R \circ R$.

In the graph theoretic representation of relations as (directed loop) graphs, a graph is dense if for every pair of vertices $a:V$ and $b:V$ with an edge $a \to b$, there exists a vertex $c:V$ with edges $a \to c$ and $c \to b$.

 Examples

• Every reflexive relation is a dense relation

• Every (left or right) Euclidean relation is a dense relation

• An idempotent relation is a dense transitive relation

 Generalizations

The notion of dense relation in Rel can in theory be generalized to the notion of a dense morphism of an arbitrary 2-poset: Given a 2-poset $C$ and an object $A \in \mathrm{Ob}(C)$, a morphism $R \in \mathrm{Hom}(A, A)$ is dense if $R \leq R \circ R$.

Dense relation structures

In dependent type theory, the usual definition of a dense relation above use the phrase “there exists…”. This existence in the definitions is mere existence; i.e. using the existential quantifier rather than the dependent sum type.

The untruncated version of the dense relation using dependent sum types can be called dense relation structure, and fields states that

• for all $x:A$ and $y:A$ such that $R(x, y)$, there exists as structure an element $z:A$ such that $R(x, z)$ and $R(z, y)$.

Related concepts

• DLO

• dense

• transitive relation

References

See also:

• Wikipedia, Dense order – Generalizations