Initial topology explained

with respect to a family of functions on

that makes those functions continuous.

The subspace topology and product topology constructions are both special cases of initial topologies. Indeed, the initial topology construction can be viewed as a generalization of these.

The dual notion is the final topology, which for a given family of functions mapping to a set

is the finest topology on

that makes those functions continuous.

Definition

Given a set

and an indexed family

\left(Y_i\right)_i

of topological spaces with functions

f_i : X \to Y_i,

the initial topology

\tau

is the coarsest topology on

such that each

f_i : (X, \tau) \to Y_i

is continuous.

Definition in terms of open sets

\left(\tau_i\right)_i

is a family of topologies

indexed by

I ≠ \varnothing,

then the of these topologies is the coarsest topology on

that is finer than each

\tau_i.

This topology always exists and it is equal to the topology generated by

{stylecup\limits_i\tau_i}.

If for every

i\inI,

\sigma_i

denotes the topology on

Y_i,

then

	-1
f
	i

\left(\sigma_i\right)=

	-1
\left\{f
	i

(V):V\in\sigma_i\right\}

is a topology on

, and the is the least upper bound topology of the

-indexed family of topologies

	-1
f
	i

\left(\sigma_i\right)

(for

i\inI

). Explicitly, the initial topology is the collection of open sets generated by all sets of the form

	-1
f
	i

(U),

where

is an open set in

Y_i

for some

i\inI,

under finite intersections and arbitrary unions.

Sets of the form

	-1
f
	i

(V)

are often called . If

contains exactly one element, then all the open sets of the initial topology

(X,\tau)

are cylinder sets.

Examples

Several topological constructions can be regarded as special cases of the initial topology.

The subspace topology is the initial topology on the subspace with respect to the inclusion map.
The product topology is the initial topology with respect to the family of projection maps.
The inverse limit of any inverse system of spaces and continuous maps is the set-theoretic inverse limit together with the initial topology determined by the canonical morphisms.
The weak topology on a locally convex space is the initial topology with respect to the continuous linear forms of its dual space.
Given a family of topologies

\left\{\tau_i\right\}

on a fixed set

the initial topology on

with respect to the functions

\operatorname{id}_i:X\to\left(X,\tau_i\right)

is the supremum (or join) of the topologies

\left\{\tau_i\right\}

in the lattice of topologies on

That is, the initial topology

\tau

is the topology generated by the union of the topologies

\left\{\tau_i\right\}.

A topological space is completely regular if and only if it has the initial topology with respect to its family of (bounded) real-valued continuous functions.
Every topological space

has the initial topology with respect to the family of continuous functions from

to the Sierpiński space.

Properties

Characteristic property

The initial topology on

can be characterized by the following characteristic property:
A function

from some space

is continuous if and only if

f_i\circg

is continuous for each

i\inI.

Note that, despite looking quite similar, this is not a universal property. A categorical description is given below.

l{B}

converges to a point

x\inX

if and only if the prefilter

f_i(l{B})

converges to

f_i(x)

for every

i\inI.

Evaluation

By the universal property of the product topology, we know that any family of continuous maps

f_i:X\toY_i

determines a unique continuous map

\beginf :\;&& X &&\;\to \;& \prod_i Y_i \\[0.3ex] && x &&\;\mapsto\;& \left(f_i(x)\right)_ \\\end

This map is known as the .

A family of maps

\{f_i:X\toY_i\}

is said to in

if for all

x ≠ y

there exists some

such that

f_i(x) ≠ f_i(y).

The family

\{f_i\}

separates points if and only if the associated evaluation map

is injective.

The evaluation map

will be a topological embedding if and only if

has the initial topology determined by the maps

\{f_i\}

and this family of maps separates points in

Hausdorffness

has the initial topology induced by

\left\{f_i:X\toY_i\right\}

and if every

Y_i

is Hausdorff, then

is a Hausdorff space if and only if these maps separate points on

Transitivity of the initial topology

has the initial topology induced by the

-indexed family of mappings

\left\{f_i:X\toY_i\right\}

and if for every

i\inI,

the topology on

Y_i

is the initial topology induced by some

J_i

-indexed family of mappings

\left\{g_j:Y_i\toZ_j\right\}

(as

ranges over

J_i

), then the initial topology on

induced by

\left\{f_i:X\toY_i\right\}

is equal to the initial topology induced by the

{stylecup\limits_iJ_i}

-indexed family of mappings

\left\{g_j\circf_i:X\toZ_j\right\}

ranges over

and

ranges over

J_i.

Several important corollaries of this fact are now given.

In particular, if

S\subseteqX

then the subspace topology that

inherits from

is equal to the initial topology induced by the inclusion map

S\toX

(defined by

s\mapstos

). Consequently, if

has the initial topology induced by

\left\{f_i:X\toY_i\right\}

then the subspace topology that

inherits from

is equal to the initial topology induced on

by the restrictions

\left\{\left.f_i\right|_S:S\toY_i\right\}

of the

f_i

The product topology on

\prod_iY_i

is equal to the initial topology induced by the canonical projections

\operatorname{pr}_i:\left(x_k\right)_k\mapstox_i

ranges over

Consequently, the initial topology on

induced by

\left\{f_i:X\toY_i\right\}

is equal to the inverse image of the product topology on

\prod_iY_i

by the evaluation map

f : X \to \prod_i Y_i\,.

Furthermore, if the maps

\left\{f_i\right\}_i

separate points on

then the evaluation map is a homeomorphism onto the subspace

f(X)

of the product space

\prod_iY_i.

Separating points from closed sets

If a space

comes equipped with a topology, it is often useful to know whether or not the topology on

is the initial topology induced by some family of maps on

This section gives a sufficient (but not necessary) condition.

A family of maps

\left\{f_i:X\toY_i\right\}

separates points from closed sets in

if for all closed sets

and all

x\not\inA,

there exists some

such that

f_i(x) \notin \operatorname(f_i(A))

where

\operatorname{cl}

denotes the closure operator.

Theorem. A family of continuous maps

\left\{f_i:X\toY_i\right\}

separates points from closed sets if and only if the cylinder sets

	-1
f
	i

(V),

for

open in

Y_i,

form a base for the topology on

It follows that whenever

\left\{f_i\right\}

separates points from closed sets, the space

has the initial topology induced by the maps

\left\{f_i\right\}.

The converse fails, since generally the cylinder sets will only form a subbase (and not a base) for the initial topology.

If the space

is a T₀ space, then any collection of maps

\left\{f_i\right\}

that separates points from closed sets in

must also separate points. In this case, the evaluation map will be an embedding.

Initial uniform structure

See main article: Uniform space.

\left(l{U}_i\right)_i

is a family of uniform structures on

indexed by

I ≠ \varnothing,

then the of

\left(l{U}_i\right)_i

is the coarsest uniform structure on

that is finer than each

l{U}_i.

This uniform always exists and it is equal to the filter on

X x X

generated by the filter subbase

{stylecup\limits_il{U}_i}.

\tau_i

is the topology on

induced by the uniform structure

l{U}_i

then the topology on

associated with least upper bound uniform structure is equal to the least upper bound topology of

\left(\tau_i\right)_i.

Now suppose that

\left\{f_i:X\toY_i\right\}

is a family of maps and for every

i\inI,

let

l{U}_i

be a uniform structure on

Y_i.

Then the is the unique coarsest uniform structure

l{U}

making all

f_i:\left(X,l{U}\right)\to\left(Y_i,l{U}_i\right)

uniformly continuous. It is equal to the least upper bound uniform structure of the

-indexed family of uniform structures

	-1
f
	i

\left(l{U}_i\right)

(for

i\inI

). The topology on

induced by

l{U}

is the coarsest topology on

such that every

f_i:X\toY_i

is continuous. The initial uniform structure

l{U}

is also equal to the coarsest uniform structure such that the identity mappings

\operatorname{id}:\left(X,l{U}\right)\to\left(X,

	-1
f
	i

\left(l{U}_{i\right)\right)}

are uniformly continuous.

Hausdorffness: The topology on

induced by the initial uniform structure

l{U}

is Hausdorff if and only if for whenever

x,y\inX

are distinct (

x ≠ y

) then there exists some

i\inI

and some entourage

V_i\inl{U}_i

Y_i

such that

\left(f_i(x),f_i(y)\right)\not\inV_i.

Furthermore, if for every index

i\inI,

the topology on

Y_i

induced by

l{U}_i

is Hausdorff then the topology on

induced by the initial uniform structure

l{U}

is Hausdorff if and only if the maps

\left\{f_i:X\toY_i\right\}

separate points on

(or equivalently, if and only if the evaluation map

f : X \to \prod_i Y_i

is injective)

Uniform continuity: If

l{U}

is the initial uniform structure induced by the mappings

\left\{f_i:X\toY_i\right\},

then a function

from some uniform space

into

(X,l{U})

is uniformly continuous if and only if

f_i\circg:Z\toY_i

is uniformly continuous for each

i\inI.

l{B}

is a Cauchy filter on

(X,l{U})

if and only if

f_{i\left(l{B}\right)}

is a Cauchy prefilter on

Y_i

for every

i\inI.

Transitivity of the initial uniform structure: If the word "topology" is replaced with "uniform structure" in the statement of "transitivity of the initial topology" given above, then the resulting statement will also be true.

Categorical description

In the language of category theory, the initial topology construction can be described as follows. Let

be the functor from a discrete category

to the category of topological spaces

Top

which maps

j\mapstoY_j

. Let

be the usual forgetful functor from

Top

Set

. The maps

f_j:X\toY_j

can then be thought of as a cone from

UY.

That is,

(X,f)

is an object of

Cone(UY):=(\Delta\downarrow{UY})

- the category of cones to

UY.

More precisely, this cone

(X,f)

defines a

-structured cosink in

Set.

The forgetful functor

U:Top\toSet

induces a functor

\bar{U}:Cone(Y)\toCone(UY)

. The characteristic property of the initial topology is equivalent to the statement that there exists a universal morphism from

\bar{U}

(X,f);

that is, a terminal object in the category

\left(\bar{U}\downarrow(X,f)\right).

Explicitly, this consists of an object

I(X,f)

Cone(Y)

together with a morphism

\varepsilon:\bar{U}I(X,f)\to(X,f)

such that for any object

(Z,g)

Cone(Y)

and morphism

\varphi:\bar{U}(Z,g)\to(X,f)

there exists a unique morphism

\zeta:(Z,g)\toI(X,f)

such that the following diagram commutes:The assignment

(X,f)\mapstoI(X,f)

placing the initial topology on

extends to a functor

I:Cone(UY)\toCone(Y)

which is right adjoint to the forgetful functor

\bar{U}.

In fact,

is a right-inverse to

\bar{U}

; since

\bar{U}I

is the identity functor on

Cone(UY).

Bibliography

- - - - Book: Willard, Stephen . General Topology . registration . Addison-Wesley . Reading, Massachusetts . 1970 . 0-486-43479-6.

Notes and References

Book: Adamson, Iain T. . https://link.springer.com/chapter/10.1007%2F978-0-8176-8126-5_3 . A General Topology Workbook . Induced and Coinduced Topologies . 1996 . Birkhäuser, Boston, MA . July 21, 2020 . ... the topology induced on E by the family of mappings ... . 10.1007/978-0-8176-8126-5_3. 23–30 . 978-0-8176-3844-3 .