nLab locale (Rev #34)

Context

Topos Theory

Topology

Idea and motivation
Definition
Properties
Related concepts
Examples
References

Idea and motivation

A locale is, intuitively, like a topological space that may or may not have enough points (or even any points at all). It contains things we call “open sets” but there may or may not be enough points to distinguish between open sets. An “open set” in a locale can be regarded as conveying a bounded amount of information about the (hypothetical) points that it contains. For example, there is a locale of all surjections from the natural numbers $N$ to the real numbers $R$ . It has no points, since there are no such surjections, but it contains many nontrivial “open sets;” these open sets are generated by a family parametrised by $n: N$ and $x: R$ that may be described as $\{f:N\to R | f$ is a surjection and $f(n) = x\}$ .

Every topological space can be regarded as a locale (with a little bit of lost information if the space is not sober). Conversely, every locale induces a topology on its set of points, but sometimes a great deal of information is lost; there are many different locales whose space of points is empty. We say that a locale is spatial if it can be recovered from its space of points.

One motivation for locales is that since they take the notion of “open set” as basic, with the points (if any) being a derived notion, they are exactly what is needed to define sheaves. The notion of sheaf on a topological space only refers to the open sets, rather than the points, so it carries over word-for-word to a definition of sheaves on locales. Moreover, passage from locales to their toposes of sheaves is a full and faithful functor, unlike for topological spaces.

Another advantage of locales is that they are better-behaved than topological spaces in constructive mathematics or internal to an arbitrary topos. For example, constructively the topological space $[0,1]$ need not be compact, but the locale $[0,1]$ is always compact (in a suitable sense). It follows that the locale $[0,1]$ , and hence also the locale $R$ of real numbers, is not always spatial. When it fails to be spatial, because there are “not enough real numbers,” the locale is generally a better-behaved object than the topological space of real numbers.

Definition

A frame $A$ is a poset with all joins and all finite meets which satisfies the infinite distributive law:

x \wedge (\bigvee_i y_i) = \bigvee_i (x\wedge y_i).

A frame homomorphism $\phi: A\to B$ is a function which preserves finite meets and arbitrary joins. Frames and frame homomorphisms form a category Frm.

Note: By the adjoint functor theorem (AFT) for posets, a frame also has all meets, but a frame homomorphism need not preserve them. Again by the AFT, a frame is automatically a Heyting algebra, but again a frame homomorphism need not preserve the Heyting implication.

The category Locale of locales is the opposite of the category of frames

Loc := Frm^{op} \,.

That is, a locale $X$ “is” a frame, which we often write as $O(X)$ and call “the frame of open sets in $X$ ”, and a continuous map $f:X\to Y$ of locales is a frame homomorphism $f^*:O(Y)\to O(X)$ . If you think of a frame as an algebraic structure (a lattice satisfying a completeness condition), then this is an example of the duality of space and quantity.

Properties

Category of locales

The category Locale of locales internal to a topos $E$ is equivalent to the category of localic geometric morphisms $E \to S$ in Topos.

Locale(S) \simeq (Topos/S)_{loc} \,.

See localic geometric morphism for more.

Relation to topological spaces

Every topological space $X$ has a frame of open sets $O(X)$ , and therefore gives rise to a locale $X_l$ . For every continuous function $f:X\to Y$ between spaces, the inverse image map $f^{-1}:O(Y)\to O(X)$ is a frame homomorphism, so $f$ induces a continuous map $f_l:X_l\to Y_l$ of locales. Thus we have a functor $(-)_l:Top \to Locale$ .

Conversely, if $X$ is any locale, we define a point of $X$ to be a continuous map $1\to X$ . Here $1$ is the terminal locale, which can be defined as the locale $1_l$ corresponding to the terminal space. Explicitly, we have $O(1) = P(1)$ , the powerset of $1$ (the initial frame, the set of truth values, which is 2 classically or in a Boolean topos). Since a frame homomorphism $O(X)\to P(1)$ is determined by the preimage of $1$ , a point can also be described more explicitly as a completely prime filter: an upwards-closed subset $F$ of $O(X)$ such that $X\in F$ ( $X$ denotes the top element of $O(X)$ ), if $U,V\in F$ then $U\cap V\in F$ , and if $\bigcup_i U_i\in F$ then $U_i\in F$ for some $i$ .

The elements of $O(X)$ induce a topology on the set of points of $X$ in an obvious way, thereby giving rise to a topological space $X_p$ . Any continuous map $f:X\to Y$ of locales induces a continuous map $f_p:X_p\to Y_p$ of spaces, so we have another functor $(-)_P:Loc\to Top$ .

It is not hard to check that $(-)_l$ is left adjoint to $(-)_p$ . In fact, this is an idempotent adjunction, and therefore it restricts to an equivalence between the fixed subcategories on either side. A space with $X\cong X_{lp}$ is called sober, while a locale with $X\cong X_{pl}$ is called spatial.

Relation to toposes

The frame of opens $O(X)$ corresponding to a locale $X$ is naturally a site:

Definition

Given a locale $X$ , with frame of open $O(X)$ , say that a family of morphisms $\{U_i \to U\}$ in $O(X)$ is a cover if $U$ is the join of the $U_i$ :

U = \vee_i U_i \,.

Proposition

This defines a coverage on $O(X)$ and hence makes it a site.

For instance (MacLaneMoerdijk, section 5).

Definition

For $X$ a locale, write

Sh(X) := Sh(O(X))

for the sheaf topos over the category $O(X)$ equipped with the above canonical structure of a site.

Write Topos for the category of Grothendieck toposes and geometric morphisms.

Proposition

This construction defines a full and faithful functor $Sh(-) :$ Locale $\to$ Topos.

This appears for instance as MacLaneMoerdijk, section IX.5 prop 2.

Definition

A topos in the image of $Sh(-) : Loc \to Topos$ is called a localic topos.

Proposition

The functor $Sh(-) : Loc \to Topos$ has a left adjoint

L : Topos \to Locale

given by sending a topos $\mathcal{E}$ to the locale that is formally dual to the frame of subobjects of the terminal object of $\mathcal{E}$ :

O(L(\mathcal{E})) := Sub_{\mathcal{E}}(*) \,.

This appears for instance as MacLaneMoerdijk, section IX.5 prop 3.

The functor $L$ here is also called localic reflection.

In summary this means that locales form a reflective subcategory or Topos

Locale \stackrel{\overset{L}{\leftarrow}}{\hookrightarrow} Topos

Proposition

The poset of subobjects $Sub_{\mathca{E}}(*)$ of the terminal object of $\mathcal{E}$ is equivalent to the full subcategory $\tau_{\leq -1}(\mathcal{E})$ of $\mathcal{E}$ on the $(-1)$ -truncated objects of $E$ .

Sub_{\mathcal{E}}(*) \simeq \tau_{\leq -1} \mathcal{E} \,.

Proof

A $(-1)$ -truncated sheaf $X$ is one whose values over any object are either the singleton set, or the empty set

X(X) \in \{*, \emptyset\} = \subset Set \,.

A monomorphism of sheaves is a natural transformation that is degreewise a monomorphism of sets. Therefore the subobjects of the terminal sheaf (that assigns the singleton set to every object) are precisely the sheaves of this form.

We may think of a frame as a (0,1)-topos. Then localic reflection is reflection of 1-toposes onto $(0,1)$ -toposes and is given by $(-1)$ -truncation: for $X$ a locale, $Sh(X)$ the corresponding localic topos and $\mathcal{E}$ any Grothendieck topos we have a natural equivalence

1Topos( \mathcal{E}, Sh X) \simeq (0,1)Topos(\tau_{\leq -1} \mathcal{E}, O(X))

which is

\cdots \simeq Frame(O(X), Sub_{mathcal{E}}(*)) \simeq Locale(L \mathcal{E} , X) \,.

This is the beginning of a pattern in higher topos theory, described at n-localic (∞,1)-topos.

Related concepts

The notion of locale may be identified with that of a Grothendieck (0,1)-topos. See Heyting algebra for more on this.
A ionad is supposed to be to a topological space as a Grothendieck topos is to a locale.
A group object internal to locales or an internal groupoid in locales is a localic group or localic groupoid, respectively.

Examples

References

An introduction to and survey of the use of locales instead of topological spaces is

Peter Johnstone, The point of pointless topology , Bull. Amer. Math. Soc. (N.S.) Volume 8, Number 1 (1983), 41-53. (Bulletin AMS)

This is, in its own words, to be read as the trailer for the book

Peter Johnstone, Stone Spaces

that develops, among other things, much of standard topology entirely with the notion of locale used in place of that of topological spaces. See Stone Spaces for details.

nLab locale (Rev #34)

Context

Topos Theory

Background

Toposes

Internal Logic

Topos morphisms

Extra stuff, structure, properties

Cohomology and homotopy

In higher category theory

Theorems

Topology

Contents

Idea and motivation

Definition

Properties

Category of locales

Relation to topological spaces

Relation to toposes

Definition

Proposition

Definition

Proposition

Definition

Proposition

Proposition

Proof

Related concepts

Examples

References