Order embedding

In order theory, a branch of mathematics, an order embedding is a special kind of monotone function, which provides a way to include one partially ordered set into another. Like Galois connections, order embeddings constitute a notion which is strictly weaker than the concept of an order isomorphism. Both of these weakenings may be understood in terms of category theory.

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Formal definition

Formally, given two partially ordered sets (posets) $(S,\leq )$ and $(T,\preceq )$ , a function $f:S\to T$ is an order embedding if $f$ is both order-preserving and order-reflecting, i.e. for all $x$ and $y$ in $S$ , one has

x\leq y{\text{ if and only if }}f(x)\preceq f(y).

^[1]

Such a function is necessarily injective, since $f(x)=f(y)$ implies $x\leq y$ and $y\leq x$ .^[1] If an order embedding between two posets $S$ and $T$ exists, one says that $S$ can be embedded into $T$ .

Properties

An order isomorphism can be characterized as a surjective order embedding. As a consequence, any order embedding f restricts to an isomorphism between its domain S and its image f(S), which justifies the term "embedding".^[1] On the other hand, it might well be that two (necessarily infinite) posets are mutually order-embeddable into each other without being order-isomorphic.

An example is provided by the open interval $(0,1)$ of real numbers and the corresponding closed interval $[0,1]$ . The function $f(x)=(94x+3)/100$ maps the former to the subset $(0.03,0.97)$ of the latter and the latter to the subset $[0.03,0.97]$ of the former, see picture. Ordering both sets in the natural way, $f$ is both order-preserving and order-reflecting (because it is an affine function). Yet, no isomorphism between the two posets can exist, since e.g. $[0,1]$ has a least element while $(0,1)$ does not. For a similar example using arctan to order-embed the real numbers into an interval, and the identity map for the reverse direction, see e.g. Just and Weese (1996).^[2]

A retract is a pair $(f,g)$ of order-preserving maps whose composition $g\circ f$ is the identity. In this case, $f$ is called a coretraction, and must be an order embedding.^[3] However, not every order embedding is a coretraction. As a trivial example, the unique order embedding $f:\emptyset \to \{1\}$ from the empty poset to a nonempty poset has no retract, because there is no order-preserving map $g:\{1\}\to \emptyset$ . More illustratively, consider the set $S$ of divisors of 6, partially ordered by x divides y, see picture. Consider the embedded sub-poset $\{1,2,3\}$ . A retract of the embedding $id:\{1,2,3\}\to S$ would need to send $6$ to somewhere in $\{1,2,3\}$ above both $2$ and $3$ , but there is no such place.

Additional Perspectives

Posets can straightforwardly be viewed from many perspectives, and order embeddings are basic enough that they tend to be visible from everywhere. For example:

(Model theoretically) A poset is a set equipped with a (reflexive, antisymmetric and transitive) binary relation. An order embedding A → B is an isomorphism from A to an elementary substructure of B.
(Graph theoretically) A poset is a (transitive, acyclic, directed, reflexive) graph. An order embedding A → B is a graph isomorphism from A to an induced subgraph of B.
(Category theoretically) A poset is a (small, thin, and skeletal) category such that each homset has at most one element. An order embedding A → B is a full and faithful functor from A to B which is injective on objects, or equivalently an isomorphism from A to a full subcategory of B.

References

^ ^a ^b ^c Davey, B. A.; Priestley, H. A. (2002), "Maps between ordered sets", Introduction to Lattices and Order (2nd ed.), New York: Cambridge University Press, pp. 23–24, ISBN 0-521-78451-4, MR 1902334.
^ Just, Winfried; Weese, Martin (1996), Discovering Modern Set Theory: The basics, Fields Institute Monographs, vol. 8, American Mathematical Society, p. 21, ISBN 9780821872475
^ Duffus, Dwight; Laflamme, Claude; Pouzet, Maurice (2008), "Retracts of posets: the chain-gap property and the selection property are independent", Algebra Universalis, 59 (1–2): 243–255, arXiv:math/0612458, doi:10.1007/s00012-008-2125-6, MR 2453498, S2CID 14259820.

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 Ordered vector space Partially ordered Positive cone Riesz space Upper set Young's lattice

This page was last edited on 15 December 2022, at 20:41

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