Difference between revisions of "Partial ordering"

Revision as of 10:01, 20 February 2016

Note to reader: this page defines [ilmath]\sqsubseteq[/ilmath] as the partial ordering under study, this is to try and make the concept distinct from [ilmath]\le[/ilmath], which the reader should have been familiar with from a young age (and thus can taint initial study)

Definition

Given a relation, [ilmath]\sqsubseteq[/ilmath] in [ilmath]X[/ilmath] (mathematically: [ilmath]\sqsubseteq\subseteq X\times X[/ilmath]^{[Note 1]}) we say [ilmath]\sqsubseteq[/ilmath] is a partial order^[1][2][3] if:

• The relation [ilmath]\sqsubseteq[/ilmath] is all 3 of the following:

• Note: [ilmath]\le[/ilmath], [ilmath]\preceq[/ilmath] or [ilmath]\subseteq[/ilmath]^{[Warning 1]} are all commonly used for partial relations too.
  • The corresponding strict partial orderings are [ilmath]<[/ilmath], [ilmath]\prec[/ilmath] and [ilmath]\subset[/ilmath]

Alternative definition

Alternatively, a partial order is simply a preorder that is also anti-symmetric (AKA Identitive), that is to say^[4]:

• Given a preorder in [ilmath]X[/ilmath], so a [ilmath]\preceq[/ilmath] such that [ilmath]\preceq\subseteq X\times X[/ilmath], then [ilmath]\preceq[/ilmath] is also a partial order if:
• [ilmath]\forall x,y\in X[((x,y)\in\preceq\wedge(y,x)\in\preceq)\implies (x=y)][/ilmath] or equivalently
  • [ilmath]\forall x,y\in X[(x\preceq y\wedge y\preceq x)\implies(x=y)][/ilmath]

Terminology

A tuple consisting of a set [ilmath]X[/ilmath] and a partial order [ilmath]\sqsubseteq[/ilmath] in [ilmath]X[/ilmath] is called a poset^[4], then we may say that:

• [ilmath](X,\sqsubseteq)[/ilmath] is a poset.

Notation

Be careful, as [ilmath]\preceq[/ilmath], [ilmath]\le[/ilmath] and [ilmath]\sqsubseteq[/ilmath] are all used to denote both partial and preorders, so always be clear which one you mean at the point of definition. That is to say write:

• Let [ilmath](X,\preceq)[/ilmath] be a partial ordering in [ilmath]X[/ilmath]. Or
• Given any [ilmath]\preceq[/ilmath] that is a partial order of [ilmath]X[/ilmath]

So forth

Induced strict partial ordering

Here, let [ilmath]\preceq[/ilmath] be a partial ordering as defined above, then the relation, [ilmath]\prec[/ilmath] defined by:

• [ilmath](x,y)\in\prec\iff[x\ne y\wedge x\preceq y][/ilmath]

is a strict partial ordering

• Note: every strict partial ordering induces a partial ordering, given a strict partial ordering, [ilmath]<[/ilmath], we can define a relation [ilmath]\le[/ilmath] as:
  • [ilmath]x\le y\iff[x=y\vee x<y][/ilmath] or equivalently (in relational form): [ilmath](x,y)\in\le\iff[x=y\vee (x,y)\in<][/ilmath]

In fact there is a 1:1 correspondence between partial and strict partial orderings, this is why the term "partial ordering" is used so casually, as given a strict you have a partial, given a partial you have a strict.

• See Overview of partial orders for more information

See also

• Poset - the term a tuple consisting of a set equipped with a partial order
• Preorder - like a partial order except it need not be anti-symmetric (AKA identitive)
  • Preset (is to preorder as poset is to partial order) - a tuple consisting of a set and a pre-order on it.
• Strict partial order - which induces and is induced by the same partial order, thus an equivalent statement to a partial order

Notes

1. ↑ Here [ilmath]\sqsubseteq[/ilmath] is the name of the relation, so [ilmath](x,y)\in \sqsubseteq[/ilmath] means [ilmath]x\sqsubseteq y[/ilmath] - as usual for relations

Warnings

1. ↑ I avoid using [ilmath]\subseteq[/ilmath] for anything other than denoting subsets, the relation and the set it relates on will go together, so you'll already be using [ilmath]\subseteq[/ilmath] to mean subset

References

1. ↑ Analysis - Part 1: Elements - Krzysztof Maurin
2. ↑ Set Theory - Thomas Jech - Third millennium edition, revised and expanded
3. ↑ Real and Abstract Analysis - Edwin Hewitt & Karl Stromberg
4. ↑ ^{4.0 4.1} An Introduction to Category Theory - Harold Simmons - 1st September 2010 edition