nLab canonical extension

Contents

Context

$(0,1)$ -Category theory

Idea
Definition

For distributive lattices
For Heyting algebras
For coherent categories
For Heyting categories

Related concepts
References

Idea

Canonical extension provides an algebraic formulation of duality theory and a tool to derive representation theorems. It may be regarded as an algebraic formulation of Stone duality (see Gehrke-Vosmaer, p. 5).

Originally (Jonsson-Tarski) is was formulated for Boolean algebras with operators, but the notion was later generalized to distributive lattices and even to arbitrary posets.

Definition

For distributive lattices

Given a distributive lattice $L$ , its canonical extension $L^\delta$ is the downset lattice of the poset of prime filters of $L$ , ordered by inclusion.

This construction extends to a functor

(-)^\delta : DistLattice \to DistLattice^+

from the category of distributive lattices to that of completely distributive algebraic lattices. This is left adjoint to the corresponding forgetful functor, exhibiting completely distributive algebraic lattices as a reflective subcategory of the distributive lattices

DistLattice^+ \stackrel{\overset{(-)^\delta}{\leftarrow}}{\hookrightarrow} DistLattice \,.

For Heyting algebras

The canonical extension $L^\delta$ of a distributive lattice $L$ is a complete and completely distributive lattice.

In particular the canonical extension is a Heyting algebra. If $L$ is itself already a Heyting algebra, then $e_L : L \to L^\delta$ preserves the Heyting implication. Also, canonical extension preserves homomorphisms of Heyting algebras. Hence it restricts to a functor

(-)^\delta : HeytingAlgebra \to HeytingAlgebra \,.

For coherent categories

A distributive lattice is a cogerent (0,1)-category. One may therefore ask if there is a generalization of canonical extension to general coherent categories.

The following is considered in (Coumans).

By the discussion at coherent category and coherent hyperdoctrine, we have a reflective sub-2-category embedding

(\mathcal{A} \dashv \mathcal{S}) : CoherentCat \hookrightarrow CoherentHyperdoctrine

given by sending a coherent category $C$ to its self-indexing $c \mapsto C_{/c}$ .

Since a coherent hyperdoctrine takes values in distributive lattices, we can apply canonical extension of distributive lattices termwise to get a functor

(-)^\delta : CoherentHyperdoctrine \to CoherentHyperdoctrine \,.

Define then canonical extension of coherent categories to be the 2-functor induced from this under the above reflection:

(-)^\delta : CoherentCat \stackrel{\mathcal{S}}{\to} CoherentHyperdoctrine \stackrel{(-)^\delta}{\to} CoherentHyperdoctrine \stackrel{\mathcal{A}}{\to} CoherentCat \,.

Under the restriction along the inclusion $DistLat \hookrightarrow CoherentCat$ this reproduces the canonical extension of distributive lattices: for $L$ a dsitributive lattice there is an equivalence

\mathcal{A}(\mathcal{S}_L^\delta) \simeq L^\delta \,.

(This is (Coumans, prop 12)).

For Heyting categories

There is also a joint generalization of canonical extension for Heyting algebras (here) and for coherent categories (here).

Write $HeytingCat$ for the 2-category of Heyting categories, and $FirstOrderHyperdoctrine$ for the 2-category of first-order hyperdoctrines (which are, in particular, hyperdoctrines with values in Heyting algebras).

Then the above restricts to a reflective sub-2-category inclusion

(\mathcal{A} \dashv \mathcal{S}) : HeyteingCat \hookrightarrow FirstOrderHyperdoctrine

This is (Coumans, prop. 19).

And the canonical extension of coherent categories accordingly restricts to a functor on Heyting categories

(-)^\delta : HeytingCat \to HeytingCat \,.

Such that for $C$ a Heyting category, also the unit $C \to C^\delta$ is a morpjism of Heyting categories.

This is (Coumans, cor. 21).

Related concepts

topos of types

References

The study of canonical extensions originates in the articles

B. Jónsson, Alfred Tarski, Boolean algebras with operators, I, Amer. J. Math. 73 (1951), 891–939.

Reviews include

Mai Gehrke, Jacob Vosmaer, A view of canonical extension (arXiv:1009.2803)

Dion Coumans, Generalizing canonical extensions to the categorical setting, pdf, to appear in Annals of Pure and Applied Logic

Last revised on July 24, 2012 at 04:00:16. See the history of this page for a list of all contributions to it.