Definition:Preordering

Definition
Let $S$ be a set.

A preordering on $S$ is a relation $\mathcal R$ on $S$ such that:


 * $\mathcal R$ is reflexive, that is, $\forall a \in S: a \mathop {\mathcal R} a$
 * $\mathcal R$ is transitive, that is, $\forall a, b, c \in S: a \mathop {\mathcal R} b \land b \mathop {\mathcal R} c \implies a \mathop {\mathcal R} c$.

Symbols used to define such a general preordering relation are often variants on $\lesssim$, $\precsim$ or $\precapprox$.

A symbol for a preordering can be reversed, and the sense is likewise inverted:


 * $a \precsim b \iff b \succsim a$

A preordered set is a set $S$ endowed with a preorder.

This can be expressed as the relational structure $\left({S, \precsim}\right)$.

Ordering
If a preordering is also antisymmetric, that is, $\forall a, b \in S: a \mathop {\mathcal R} b \land b \mathop {\mathcal R} a \implies a = b$, then $\mathcal R$ is an ordering.

Equivalence Relation
If a preordering is also symmetric, that is, $\forall a, b \in S: a \mathop {\mathcal R} b \implies b \mathop {\mathcal R} a$, then $\mathcal R$ is an equivalence relation.

Partial vs. Total Preorderings
Note that this definition of preordering does not demand that every pair of elements of $S$ is related by $\precsim$. The way we have defined a preordering, they may be, or they may not be, depending on the context.

If it is the case that $\precsim$ is a connected relation, i.e. that every pair of elements is related by $\precsim$, then $\precsim$ is called a total preordering.

If it is not the case that $\precsim$ is connected, then $\precsim$ is called a partial preordering.

Also known as
A preordering is also known as a preorder.

Either name can be seen with a hyphen: pre-ordering and pre-order.

Some sources use the term quasiorder or quasi-order.

uses the term reflexive partial ordering, but as this can so easily be confused with the concept of a partial ordering this term is not recommended.