Quotient space (topology)

Illustration of the construction of a topological sphere as the quotient space of a disk, by gluing together to a single point the points (in blue) of the boundary of the disk.

In topology and related areas of mathematics, the quotient space of a topological space under a given equivalence relation is a new topological space constructed by endowing the quotient set of the original topological space with the quotient topology, that is, with the finest topology that makes continuous the canonical projection map (the function that maps points to their equivalence classes). In other words, a subset of a quotient space is open if and only if its preimage under the canonical projection map is open in the original topological space.

Intuitively speaking, the points of each equivalence class are identified or "glued together" for forming a new topological space. For example, identifying the points of a sphere that belong to the same diameter produces the projective plane as a quotient space.

Definition[]

Let $\left(X,\tau _{X}\right)$ be a topological space, and let $\,\sim \,$ be an equivalence relation on $X.$ The quotient set, $Y=X/\sim \,$ is the set of equivalence classes of elements of $X.$ The equivalence class of $x\in X$ is denoted $[x].$ The quotient, canonical, projection map associated with $\,\sim \,$ refers to the following surjective map:

{\begin{alignedat}{4}q:\;&&X&&~\to &~X/{\sim }\\[0.3ex]&&x&&~\mapsto &~[x].\end{alignedat}}

For any subset

S\subseteq X/{\sim }

(so in particular,

s\subseteq X

for every

s\in S

) the following holds:

q^{-1}(S)=\{x\in X:[x]\in S\}=\bigcup _{s\in S}s.

The quotient space under $\,\sim \,$ is the quotient set $Y$ equipped with the quotient topology, which is the topology whose open sets are the subsets $U\subseteq Y=X/{\sim }$ such that $\{x\in X:[x]\in U\}=\cup _{u\in U}u$ is an open subset of $\left(X,\tau _{X}\right);$ that is, $U\subseteq X/{\sim }$ is open in the quotient topology on $X/{\sim }$ if and only if $\{x\in X:[x]\in U\}\in \tau _{X}.$ Thus,

\tau _{Y}=\left\{U\subseteq Y:\{x\in X:[x]\in U\}\in \tau _{X}\right\}.

Equivalently, the open sets of the quotient topology are the subsets of

Y

that have an open preimage under the canonical map

q:X\to X/{\sim }

(which is defined by

q(x)=[x]

). Similarly, a subset

S\subseteq X/{\sim }

is closed in

X/{\sim }

if and only if

\{x\in X:[x]\in S\}

is a closed subset of

\left(X,\tau _{X}\right).

The quotient topology is the final topology on the quotient set, with respect to the map $x\mapsto [x].$

Quotient map[]

A map $f:X\to Y$ is a quotient map (sometimes called an identification map) if it is surjective, and a subset $V\subseteq Y$ is open if and only if $f^{-1}(V)$ is open. Equivalently, a surjection $f:X\to Y$ is a quotient map if and only if for every subset $D\subseteq Y,$ $D$ is closed in $Y$ if and only if $f^{-1}(D)$ is closed in $X.$

Final topology definition

Alternatively, $f$ is a quotient map if it is onto and $Y$ is equipped with the final topology with respect to $f.$

Saturated sets and quotient maps

A subset $S$ of $X$ is called saturated (with respect to $f$ ) if it is of the form $S=f^{-1}(T)$ for some set $T,$ which is true if and only if $f^{-1}(f(S))=S$ (although $f^{-1}(f(S))\supseteq S$ always holds for every subset $S\subseteq X,$ equality is in general not guaranteed; and a non-saturated set exists if and only if $f$ is not injective). The assignment $T\mapsto f^{-1}(T)$ establishes a one-to-one correspondence (whose inverse is $S\mapsto f(S)$ ) between subsets $T$ of $Y=f(X)$ and saturated subsets of $X.$ With this terminology, a surjection $f:X\to Y$ is a quotient map if and only if for every saturated subset $S$ of $X,$ $S$ is open in $X$ if and only if $f(S)$ is open in $Y.$ In particular, open subsets of $X$ that are not saturated have no impact on whether or not the function $f$ is a quotient map; non-saturated subsets are irrelevant to the definition of "quotient map" just as they are irrelevant to the open-set definition of continuity (because a function $f:X\to Y$ is continuous if and only if for every saturated subset $S$ of $X,$ $f(S)$ being open in $f(X)$ implies $S$ is open in $X$ ).

Every quotient map is continuous but not every continuous map is a quotient map. A continuous surjection $f:X\to Y$ fails to be a quotient map if and only if $X$ has some saturated open subset $S$ such that $f(S)$ is not open in $Y$ (this statement remains true if both instances of the word "open" are replaced with "closed").

Quotient space of fibers characterization

Given an equivalence relation $\,\sim \,$ on $X,$ the canonical map $q:X\to X/{\sim }$ that sends $x\in X$ to its equivalence class $[x]:=\{z\in X:z\sim x\}$ (that is, $q(x):=[x]$ ) is a quotient map that satisfies $q(x)=q^{-1}(q(x))$ for all $x\in X$ ; moreover, for all $a,b\in X,$ $a\,\sim \,b$ if and only if $q(a)=q(b).$

In fact, let $\pi :X\to Y$ be a surjection between topological spaces (not yet assumed to be continuous or a quotient map) and declare for all $a,b\in X$ that $a\,\sim \,b$ if and only if $\pi (a)=\pi (b).$ Then $\,\sim \,$ is an equivalence relation on $X$ such that for every $x\in X,$ $[x]=\pi ^{-1}(\pi (x))$ so that $\pi ([x])=\{\,\pi (x)\,\}\subseteq Y$ is a singleton set, which thus induces a bijection ${\hat {\pi }}:X/{\sim }\;\;\to \;Y$ defined by ${\hat {\pi }}([x]):=\pi (x)$ (this is well defined because $\pi ([x])$ is a singleton set and ${\hat {\pi }}([x])$ is just its unique element; that is, $\pi ([x])=\{\,{\hat {\pi }}([x])\,\}$ for every $x$ ). Define the map $q:X\to X/{\sim }$ as above (by $q(x):=[x]$ ) and give $X/\sim$ the quotient topology induced by $q$ (which makes $q$ a quotient map). These maps are related by:

\pi ={\hat {\pi }}\circ q\quad {\text{ and }}\quad q={\hat {\pi }}^{-1}\circ \pi .

From this and the fact that

q:X\to X/\sim

is a quotient map, it follows that

\pi :X\to Y

is continuous if and only if this is true of

{\hat {\pi }}:X/\sim \;\;\to \;Y.

Furthermore,

\pi :X\to Y

is a quotient map if and only if

{\hat {\pi }}:X/\sim \;\;\to \;Y

is a homeomorphism (or equivalently, if and only if both

{\hat {\pi }}

and its inverse are continuous).

Related definitions[]

A hereditarily quotient map is a surjective map $f:X\to Y$ with the property that for every subset $T\subseteq Y,$ the restriction $f{\big \vert }_{f^{-1}(T)}~:~f^{-1}(T)\to T$ is also a quotient map. There exist quotient maps that are not hereditarily quotient.

Examples[]

Gluing. Topologists talk of gluing points together. If $X$ is a topological space, gluing the points $x$ and $y$ in $X$ means considering the quotient space obtained from the equivalence relation $a\sim b$ if and only if $a=b$ or $a=x,b=y$ (or $a=y,b=x$ ).
Consider the unit square $I^{2}=[0,1]\times [0,1]$ and the equivalence relation ~ generated by the requirement that all boundary points be equivalent, thus identifying all boundary points to a single equivalence class. Then $I^{2}/\sim$ is homeomorphic to the sphere $S^{2}.$

For example,

[0,1]/\{0,1\}

is homeomorphic to the circle

S^{1}.

Adjunction space. More generally, suppose $X$ is a space and $A$ is a subspace of $X.$ One can identify all points in $A$ to a single equivalence class and leave points outside of $A$ equivalent only to themselves. The resulting quotient space is denoted $X/A.$ The 2-sphere is then homeomorphic to a closed disc with its boundary identified to a single point: $D^{2}/\partial {D^{2}}.$
Consider the set $\mathbb {R}$ of real numbers with the ordinary topology, and write $x\sim y$ if and only if $x-y$ is an integer. Then the quotient space $X/\sim$ is homeomorphic to the unit circle $S^{1}$ via the homeomorphism which sends the equivalence class of $x$ to $\exp(2\pi ix).$
A generalization of the previous example is the following: Suppose a topological group $G$ $G$ acts continuously on a space $X.$ $X.$ One can form an equivalence relation on $X$ $X$ by saying points are equivalent if and only if they lie in the same orbit. The quotient space under this relation is called the orbit space, denoted $X/G.$ $X/G.$ In the previous example $G=\mathbb {Z}$ $G=\mathbb {Z}$ acts on $\mathbb {R}$ $\mathbb {R}$ by translation. The orbit space $\mathbb {R} /\mathbb {Z}$ $\mathbb {R} /\mathbb {Z}$ is homeomorphic to $S^{1}.$ $S^{1}.$
- Note: The notation $\mathbb {R} /\mathbb {Z}$ is somewhat ambiguous. If $\mathbb {Z}$ is understood to be a group acting on $\mathbb {R}$ via addition, then the quotient is the circle. However, if $\mathbb {Z}$ is thought of as a topological subspace of $\mathbb {R}$ (that is identified as a single point) then the quotient $\{\mathbb {Z} \}\cup \{\,\{r\}:r\in \mathbb {R} \setminus \mathbb {Z} \}$ (which is identifiable with the set $\{\mathbb {Z} \}\cup (\mathbb {R} \setminus \mathbb {Z} )$ ) is a countably infinite bouquet of circles joined at a single point $\mathbb {Z} .$
This next example shows that it is in general not true that if $q:X\to Y$ is a quotient map then every convergent sequence (respectively, every convergent net) in $Y$ has a lift (by $q$ ) to a convergent sequence (or convergent net) in $X.$ Let $X=[0,1]$ and $\,\sim ~=~\{\,\{0,1\}\,\}~\cup ~\left\{\{x\}:x\in (0,1)\,\right\}.$ Let $Y:=X/\,\sim \,$ and let $q:X\to X/\sim \,$ be the quotient map $q(x):=[x],$ so that $q(0)=q(1)=\{0,1\}$ and $q(x)=\{x\}$ for every $x\in (0,1).$ The map $h:X/\,\sim \,\to S^{1}\subseteq \mathbb {C}$ defined by $h([x]):=e^{2\pi ix}$ is well-defined (because $e^{2\pi i(0)}=1=e^{2\pi i(1)}$ ) and a homeomorphism. Let $I=\mathbb {N}$ and let $a_{\bullet }:=\left(a_{i}\right)_{i\in I}{\text{ and }}b_{\bullet }:=\left(b_{i}\right)_{i\in I}$ be any sequences (or more generally, any nets) valued in $(0,1)$ such that $a_{\bullet }\to 0{\text{ and }}b_{\bullet }\to 1$ in $X=[0,1].$ Then the sequence $y_{1}:=q\left(a_{1}\right),y_{2}:=q\left(b_{1}\right),y_{3}:=q\left(a_{2}\right),y_{4}:=q\left(b_{2}\right),\ldots$ converges to $[0]=[1]$ in $X/\sim \,$ but there does not exist any convergent lift of this sequence by the quotient map $q$ (that is, there is no sequence $s_{\bullet }=\left(s_{i}\right)_{i\in I}$ in $X$ that both converges to some $x\in X$ and satisfies $y_{i}=q\left(s_{i}\right)$ for every $i\in I$ ). This counterexample can be generalized to nets by letting $(A,\leq )$ be any directed set, and making $I:=A\times \{1,2\}$ into a net by declaring that for any $(a,m),(b,n)\in I,$ $(m,a)\;\leq \;(n,b)$ holds if and only if both (1) $a\leq b,$ and (2) if $a=b{\text{ then }}m\leq n;$ then the $A$ -indexed net defined by letting $y_{(a,m)}$ equal $a_{i}{\text{ if }}m=1$ and equal to $b_{i}{\text{ if }}m=2$ has no lift (by $q$ ) to a convergent $A$ -indexed net in $X=[0,1].$

Properties[]

Quotient maps $q:X\to Y$ are characterized among surjective maps by the following property: if $Z$ is any topological space and $f:Y\to Z$ is any function, then $f$ is continuous if and only if $f\circ q$ is continuous.

Characteristic property of the quotient topology

The quotient space $X/\sim$ together with the quotient map $q:X\to X/\sim$ is characterized by the following universal property: if $g:X\to Z$ is a continuous map such that $a\sim b$ implies $g(a)=g(b)$ for all $a,b\in X,$ then there exists a unique continuous map $f:X/\sim \to Z$ such that $g=f\circ q.$ In other words, the following diagram commutes:

One says that $g$ descends to the quotient for expressing this, that is that it factorizes through the quotient space. The continuous maps defined on $X/\sim$ are therefore precisely those maps which arise from continuous maps defined on $X$ that respect the equivalence relation (in the sense that they send equivalent elements to the same image). This criterion is copiously used when studying quotient spaces.

Given a continuous surjection $q:X\to Y$ it is useful to have criteria by which one can determine if $q$ is a quotient map. Two sufficient criteria are that $q$ be open or closed. Note that these conditions are only sufficient, not necessary. It is easy to construct examples of quotient maps that are neither open nor closed. For topological groups, the quotient map is open.

Compatibility with other topological notions[]

Separation

In general, quotient spaces are ill-behaved with respect to separation axioms. The separation properties of $X$ need not be inherited by $X/\sim ,$ and $X/\sim$ may have separation properties not shared by $X.$
$X/\sim$ is a T1 space if and only if every equivalence class of $\,\sim \,$ is closed in $X.$
If the quotient map is open, then $X/\sim$ is a Hausdorff space if and only if ~ is a closed subset of the product space $X\times X.$

Connectedness

If a space is connected or path connected, then so are all its quotient spaces.
A quotient space of a simply connected or contractible space need not share those properties.

Compactness

If a space is compact, then so are all its quotient spaces.
A quotient space of a locally compact space need not be locally compact.

Dimension

The topological dimension of a quotient space can be more (as well as less) than the dimension of the original space; space-filling curves provide such examples.

References[]

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