Induced topology

In topology and related areas of mathematics, an induced topology on a topological space is a topology that makes a given (inducing) function or collection of functions continuous from this topological space.^[1][2]

A coinduced topology or final topology makes the given (coinducing) collection of functions continuous to this topological space.^[3]

Let ${\displaystyle X_0,X_1}$ be sets, ${\displaystyle f:X_0\to X_1}$.

If ${\displaystyle {\tau }_0}$ is a topology on ${\displaystyle X_0}$, then the topology coinduced on ${\displaystyle X_1}$ by ${\displaystyle f}$ is ${\displaystyle \{U_1\subseteq X_1|f^{-1}(U_1)\in {\tau }_0\}}$.

If ${\displaystyle {\tau }_1}$ is a topology on ${\displaystyle X_1}$, then the topology induced on ${\displaystyle X_0}$ by ${\displaystyle f}$ is ${\displaystyle \{f^{-1}(U_1)|U_1\in {\tau }_1\}}$.

The easy way to remember the definitions above is to notice that finding an inverse image is used in both. This is because inverse image preserves union and intersection. Finding a direct image does not preserve intersection in general. Here is an example where this becomes a hurdle. Consider a set ${\displaystyle X_0=\{-2,-1,1,2\}}$ with a topology ${\displaystyle \{\{-2,-1\},\{1,2\}\}}$, a set ${\displaystyle X_1=\{-1,0,1\}}$ and a function ${\displaystyle f:X_0\to X_1}$ such that ${\displaystyle f(-2)=-1,f(-1)=0,f(1)=0,f(2)=1}$. A set of subsets ${\displaystyle {\tau }_1=\{f(U_0)|U_0\in {\tau }_0\}}$ is not a topology, because ${\displaystyle \{\{-1,0\},\{0,1\}\}\subseteq {\tau }_1}$ but ${\displaystyle \{-1,0\}\cap \{0,1\}\notin {\tau }_1}$.

There are equivalent definitions below.

The topology ${\displaystyle {\tau }_1}$ coinduced on ${\displaystyle X_1}$ by ${\displaystyle f}$ is the finest topology such that ${\displaystyle f}$ is continuous ${\displaystyle (X_0,{\tau }_0)\to (X_1,{\tau }_1)}$. This is a particular case of the final topology on ${\displaystyle X_1}$.

The topology ${\displaystyle {\tau }_0}$ induced on ${\displaystyle X_0}$ by ${\displaystyle f}$ is the coarsest topology such that ${\displaystyle f}$ is continuous ${\displaystyle (X_0,{\tau }_0)\to (X_1,{\tau }_1)}$. This is a particular case of the initial topology on ${\displaystyle X_0}$.

Given a set X and an indexed family (Y_i)_i∈I of topological spaces with functions

${\displaystyle f_i:X\to Y_i,}$

the topology ${\displaystyle \tau }$ on ${\displaystyle X}$ induced by these functions is the coarsest topology on X such that each

${\displaystyle f_i:(X,\tau )\to Y_i}$

is continuous.^[1][2]

Explicitly, the induced topology is the collection of open sets generated by all sets of the form ${\displaystyle f_i^{-1}(U)}$, where ${\displaystyle U}$ is an open set in ${\displaystyle Y_i}$ for some i ∈ I, under finite intersections and arbitrary unions. The sets ${\displaystyle f_i^{-1}(U)}$ are often called cylinder sets. If I contains exactly one element, all the open sets of ${\displaystyle (X,\tau )}$ are cylinder sets.

• The quotient topology is the topology coinduced by the quotient map.
• The product topology is the topology induced by the projections ${\displaystyle {\text{proj}}_j:X\to X_j}$.
• If ${\displaystyle f:X_0\to X}$ is an inclusion map, then ${\displaystyle f}$ induces on ${\displaystyle X_0}$ the subspace topology.
• The weak topology is that induced by the dual on a topological vector space.^[1]

• Natural topology
• The initial topology and final topology are used synonymously, though usually only in the case where the (co)inducing collection consists of more than one function.

• Hu, Sze-Tsen (1969). Elements of general topology. Holden-Day. 

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