Suppose throughout that \, is a
homogeneous binary relation on a set S (that is, \, is a subset of S \times S) and as usual, write x and say that or if and only if (x, y) \in \,
Strict weak orderings Preliminaries on incomparability and transitivity of incomparability Two elements x and y of S are said to be '''''' with respect to \, if neither x nor y is true. The incomparability relation is always
symmetric and it will be
reflexive if and only if \, is an irreflexive relation (which is assumed by the above definition). Consequently, a strict partial order \, is a strict weak order if and only if its induced incomparability relation is an
equivalence relation. In this case, its
equivalence classes
partition S and moreover, the set \mathcal{P} of these equivalence classes can be
strictly totally ordered by a
binary relation, also denoted by \, that is defined for all A, B \in \mathcal{P} by: :A for some (or equivalently, for all) representatives a \in A \text{ and } b \in B. Conversely, any
strict total order on a
partition \mathcal{P} of S gives rise to a strict weak ordering \, on S defined by a if and only if there exists sets A, B \in \mathcal{P} in this partition such that a \in A, b \in B, \text{ and } A Not every partial order obeys the transitive law for incomparability. For instance, consider the partial order in the set \{ a, b ,c \} defined by the relationship b The pairs a, b \text{ and } a, c are incomparable but b and c are related, so incomparability does not form an equivalence relation and this example is not a strict weak ordering. For transitivity of incomparability, each of the following conditions is
necessary, and for strict partial orders also
sufficient: • If x then for all z, either x or both. • If x is incomparable with y then for all z, either (x ) or (z ) or (z is incomparable with x and z is incomparable with y).
Total preorders Strict weak orders are very closely related to
total preorders or
(non-strict) weak orders, and the same mathematical concepts that can be modeled with strict weak orderings can be modeled equally well with total preorders. A total preorder or weak order is a
preorder in which any two elements are comparable. A total preorder \,\lesssim\, satisfies the following properties: • : For all x, y, \text{ and } z, if x \lesssim y \text{ and } y \lesssim z then x \lesssim z. • : For all x \text{ and } y, x \lesssim y \text{ or } y \lesssim x. • Which implies : for all x, x \lesssim x. A
total order is a total preorder which is antisymmetric, in other words, which is also a
partial order. Total preorders are sometimes also called
preference relations. The
complement of a strict weak order is a total preorder, and vice versa, but it seems more natural to relate strict weak orders and total preorders in a way that preserves rather than reverses the order of the elements. Thus we take the
converse of the complement: for a strict weak ordering \, define a total preorder \,\lesssim\, by setting x \lesssim y whenever it is not the case that y In the other direction, to define a strict weak ordering \,\lesssim, set x whenever it is not the case that y \lesssim x. In any preorder there is a
corresponding equivalence relation where two elements x and y are defined as
equivalent if x \lesssim y \text{ and } y \lesssim x. In the case of a preorder the corresponding partial order on the set of equivalence classes is a total order. Two elements are equivalent in a total preorder if and only if they are incomparable in the corresponding strict weak ordering.
Ordered partitions A
partition of a set S is a family of non-empty disjoint subsets of S that have S as their union. A partition, together with a
total order on the sets of the partition, gives a structure called by
Richard P. Stanley an
ordered partition and by
Theodore Motzkin a
list of sets. An ordered partition of a finite set may be written as a
finite sequence of the sets in the partition: for instance, the three ordered partitions of the set \{a, b\} are \{a\}, \{b\}, \{b\}, \{a\}, \; \text{ and } \{a, b\}. In a strict weak ordering, the equivalence classes of incomparability give a set partition, in which the sets inherit a total ordering from their elements, giving rise to an ordered partition. In the other direction, any ordered partition gives rise to a strict weak ordering in which two elements are incomparable when they belong to the same set in the partition, and otherwise inherit the order of the sets that contain them.
Representation by functions For sets of sufficiently small
cardinality, a fourth axiomatization is possible, based on real-valued functions. If X is any set then a real-valued function f : X \to \R on X induces a strict weak order on X by setting a The associated total preorder is given by setting a {}\lesssim{} b \text{ if and only if } f(a) \leq f(b) and the associated equivalence by setting a {}\sim{} b \text{ if and only if } f(a) = f(b). The relations do not change when f is replaced by g \circ f (
composite function), where g is a
strictly increasing real-valued function defined on at least the range of f. Thus for example, a
utility function defines a
preference relation. In this context, weak orderings are also known as
preferential arrangements. If X is finite or countable, every weak order on X can be represented by a function in this way. However, there exist strict weak orders that have no corresponding real function. For example, there is no such function for the
lexicographic order on \R^n. Thus, while in most preference relation models the relation defines a utility function
up to order-preserving transformations, there is no such function for
lexicographic preferences. More generally, if X is a set, Y is a set with a strict weak ordering \, and f : X \to Y is a function, then f induces a strict weak ordering on X by setting a As before, the associated total preorder is given by setting a {}\lesssim{} b \text{ if and only if } f(a) {}\lesssim{} f(b), and the associated equivalence by setting a {}\sim{} b \text{ if and only if } f(a) {}\sim{} f(b). It is not assumed here that f is an
injective function, so a class of two equivalent elements on Y may induce a larger class of equivalent elements on X. Also, f is not assumed to be a
surjective function, so a class of equivalent elements on Y may induce a smaller or empty class on X. However, the function f induces an injective function that maps the partition on X to that on Y. Thus, in the case of finite partitions, the number of classes in X is less than or equal to the number of classes on Y. ==Related types of ordering==