Prewellordering

Set theory concept

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	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 $S\neq \varnothing :$	${\begin{aligned}&aRb\\\Rightarrow {}&bRa\end{aligned}}$	${\begin{aligned}aRb{\text{ and }}&bRa\\\Rightarrow a={}&b\end{aligned}}$	${\begin{aligned}a\neq {}&b\Rightarrow \\aRb{\text{ or }}&bRa\end{aligned}}$	${\begin{aligned}\min S\\{\text{exists}}\end{aligned}}$	${\begin{aligned}a\vee b\\{\text{exists}}\end{aligned}}$	${\begin{aligned}a\wedge b\\{\text{exists}}\end{aligned}}$	$aRa$	${\text{not }}aRa$	${\begin{aligned}aRb\Rightarrow \\{\text{not }}bRa\end{aligned}}$

Y 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

Y 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.

In set theory, a prewellordering on a set $X$ is a preorder $\leq$ on $X$ (a transitive and reflexive relation on $X$ ) that is strongly connected (meaning that any two points are comparable) and well-founded in the sense that the induced relation $x<y$ defined by $x\leq y{\text{ and }}y\nleq x$ is a well-founded relation.

Prewellordering on a set

A prewellordering on a set $X$ is a homogeneous binary relation $\,\leq \,$ on $X$ that satisfies the following conditions:^[1]

Reflexivity: $x\leq x$ for all $x\in X.$
Transitivity: if $x<y$ and $y<z$ then $x<z$ for all $x,y,z\in X.$
Total/Strongly connected: $x\leq y$ or $y\leq x$ for all $x,y\in X.$
for every non-empty subset $S\subseteq X,$ there exists some $m\in S$ such that $m\leq s$ for all $s\in S.$
- This condition is equivalent to the induced strict preorder $x<y$ defined by $x\leq y$ and $y\nleq x$ being a well-founded relation.

A homogeneous binary relation $\,\leq \,$ on $X$ is a prewellordering if and only if there exists a surjection $\pi :X\to Y$ into a well-ordered set $(Y,\lesssim )$ such that for all $x,y\in X,$ ${\textstyle x\leq y}$ if and only if $\pi (x)\lesssim \pi (y).$ ^[1]

Examples

{\displaystyle \lfloor x/4\rfloor \leq \lfloor y/5\rfloor } — Hasse diagram of the prewellordering $\lfloor x/4\rfloor \leq \lfloor y/5\rfloor$ on the non-negative integers, shown up to 29. Cycles are indicated in red and $\lfloor \cdot \rfloor$ denotes the floor function.

{\displaystyle \lfloor x/4\rfloor \leq \lfloor y/4\rfloor } — Hasse diagram of the prewellordering $\lfloor x/4\rfloor \leq \lfloor y/4\rfloor$ on the non-negative integers, shown up to 18. The associated equivalence relation is $\lfloor x/4\rfloor =\lfloor y/4\rfloor ;$ it identifies the numbers in each light red square.

Given a set $A,$ the binary relation on the set $X:=\operatorname {Finite} (A)$ of all finite subsets of $A$ defined by $S\leq T$ if and only if $|S|\leq |T|$ (where $|\cdot |$ denotes the set's cardinality) is a prewellordering.^[1]

Properties

If $\leq$ is a prewellordering on $X,$ then the relation $\sim$ defined by

x\sim y{\text{ if and only if }}x\leq y\land y\leq x

is an equivalence relation on

X,

and

\leq

induces a wellordering on the quotient

X/{\sim }.

The order-type of this induced wellordering is an ordinal, referred to as the length of the prewellordering.

A norm on a set $X$ is a map from $X$ into the ordinals. Every norm induces a prewellordering; if $\phi :X\to Ord$ is a norm, the associated prewellordering is given by

x\leq y{\text{ if and only if }}\phi (x)\leq \phi (y)

Conversely, every prewellordering is induced by a unique regular norm (a norm

\phi :X\to Ord

is regular if, for any

x\in X

and any

\alpha <\phi (x),

there is

y\in X

such that

\phi (y)=\alpha

Prewellordering property

If ${\boldsymbol {\Gamma }}$ is a pointclass of subsets of some collection ${\mathcal {F}}$ of Polish spaces, ${\mathcal {F}}$ closed under Cartesian product, and if $\leq$ is a prewellordering of some subset $P$ of some element $X$ of ${\mathcal {F}},$ then $\leq$ is said to be a ${\boldsymbol {\Gamma }}$ -prewellordering of $P$ if the relations $<^{*}$ and $\leq ^{*}$ are elements of ${\boldsymbol {\Gamma }},$ where for $x,y\in X,$

$x<^{*}y{\text{ if and only if }}x\in P\land (y\notin P\lor (x\leq y\land y\not \leq x))$
$x\leq ^{*}y{\text{ if and only if }}x\in P\land (y\notin P\lor x\leq y)$

${\boldsymbol {\Gamma }}$ is said to have the prewellordering property if every set in ${\boldsymbol {\Gamma }}$ admits a ${\boldsymbol {\Gamma }}$ -prewellordering.

The prewellordering property is related to the stronger scale property; in practice, many pointclasses having the prewellordering property also have the scale property, which allows drawing stronger conclusions.

Examples

${\boldsymbol {\Pi }}_{1}^{1}$ and ${\boldsymbol {\Sigma }}_{2}^{1}$ both have the prewellordering property; this is provable in ZFC alone. Assuming sufficient large cardinals, for every $n\in \omega ,$ ${\boldsymbol {\Pi }}_{2n+1}^{1}$ and ${\boldsymbol {\Sigma }}_{2n+2}^{1}$ have the prewellordering property.

Consequences

Reduction

If ${\boldsymbol {\Gamma }}$ is an adequate pointclass with the prewellordering property, then it also has the reduction property: For any space $X\in {\mathcal {F}}$ and any sets $A,B\subseteq X,$ $A$ and $B$ both in ${\boldsymbol {\Gamma }},$ the union $A\cup B$ may be partitioned into sets $A^{*},B^{*},$ both in ${\boldsymbol {\Gamma }},$ such that $A^{*}\subseteq A$ and $B^{*}\subseteq B.$

Separation

If ${\boldsymbol {\Gamma }}$ is an adequate pointclass whose dual pointclass has the prewellordering property, then ${\boldsymbol {\Gamma }}$ has the separation property: For any space $X\in {\mathcal {F}}$ and any sets $A,B\subseteq X,$ $A$ and $B$ disjoint sets both in ${\boldsymbol {\Gamma }},$ there is a set $C\subseteq X$ such that both $C$ and its complement $X\setminus C$ are in ${\boldsymbol {\Gamma }},$ with $A\subseteq C$ and $B\cap C=\varnothing .$

For example, ${\boldsymbol {\Pi }}_{1}^{1}$ has the prewellordering property, so ${\boldsymbol {\Sigma }}_{1}^{1}$ has the separation property. This means that if $A$ and $B$ are disjoint analytic subsets of some Polish space $X,$ then there is a Borel subset $C$ of $X$ such that $C$ includes $A$ and is disjoint from $B.$

References

^ ^a ^b ^c Moschovakis 2006, p. 106.

Moschovakis, Yiannis N. (1980). Descriptive Set Theory. Amsterdam: North Holland. ISBN 978-0-08-096319-8. OCLC 499778252.
Moschovakis, Yiannis N. (2006). Notes on set theory. New York: Springer. ISBN 978-0-387-31609-3. OCLC 209913560.

v t e Order theory
Topics Glossary Category
Key concepts	Binary relation Boolean algebra Cyclic order Lattice Partial order Preorder Total order Weak ordering
Results	Boolean prime ideal theorem Cantor–Bernstein theorem Cantor's isomorphism theorem Dilworth's theorem Dushnik–Miller theorem Hausdorff maximal principle Knaster–Tarski theorem Kruskal's tree theorem Laver's theorem Mirsky's theorem Szpilrajn extension theorem Zorn's lemma
Properties & Types (list)	Antisymmetric Asymmetric Boolean algebra topics Completeness Connected Covering Dense Directed (Partial) Equivalence Foundational Heyting algebra Homogeneous Idempotent Lattice Bounded Complemented Complete Distributive Join and meet Reflexive Partial order Chain-complete Graded Eulerian Strict Prefix order Preorder Total Semilattice Semiorder Symmetric Total Tolerance Transitive Well-founded Well-quasi-ordering (Better) (Pre) Well-order
Constructions	Composition Converse/Transpose Lexicographic order Linear extension Product order Reflexive closure Series-parallel partial order Star product Symmetric closure Transitive closure
Topology & Orders	Alexandrov topology & Specialization preorder Ordered topological vector space Normal cone Order topology Order topology Topological vector lattice Banach Fréchet Locally convex Normed
Related	Antichain Cofinal Cofinality Comparability Graph Duality Filter Hasse diagram Ideal Net Subnet Order morphism Embedding Isomorphism Order type Ordered field Positive cone of an ordered field Ordered vector space Partially ordered Positive cone of an ordered vector space Riesz space Partially ordered group Positive cone of a partially ordered group Upper set Young's lattice