subspace of a subspace

Theorem 1.

Suppose $X\subseteq Y\subseteq Z$ are sets and $Z$ is a topological space with topology $\tau_{Z}$ . Let $\tau_{Y,Z}$ be the subspace topology in $Y$ given by $\tau_{Z}$ , and let $\tau_{X,Y,Z}$ be the subspace topology in $X$ given by $\tau_{Y,Z}$ , and let $\tau_{X,Z}$ be the subspace topology in $X$ given by $\tau_{Z}$ . Then $\tau_{X,Z}=\tau_{X,Y,Z}$ .

Proof.

Let $U_{X}\in\tau_{X,Z}$ , then there is by the definition of the subspace topology an open set $U_{Z}\in\tau_{Z}$ such that $U_{X}=U_{Z}\cap X$ . Now $U_{Z}\cap Y\in\tau_{Y,Z}$ and therefore $U_{Z}\cap Y\cap X\in\tau_{X,Y,Z}$ . But since $X\subseteq Y$ , we have $U_{Z}\cap Y\cap X=U_{Z}\cap X=U_{X}$ , so $U_{X}\in\tau_{X,Y,Z}$ and thus $\tau_{X,Z}\subseteq\tau_{X,Y,Z}$ .

To show the reverse inclusion, take an open set $U_{X}\in\tau_{X,Y,Z}$ . Then there is an open set $U_{Y}\in\tau_{Y,Z}$ such that $U_{X}=U_{Y}\cap X$ . Furthermore, there is an open set $U_{Z}\in\tau_{Z}$ such that $U_{Y}=U_{Z}\cap Y$ . Since $X\subseteq Y$ , we have

U_{Z}\cap X=U_{Z}\cap Y\cap X=U_{Y}\cap X=U_{X},

so $U_{X}\in\tau_{X,Z}$ and thus $\tau_{X,Y,Z}\subseteq\tau_{X,Z}$ .

Together, both inclusions yield the equality $\tau_{X,Z}=\tau_{X,Y,Z}$ . ∎

Title	subspace of a subspace
Canonical name	SubspaceOfASubspace
Date of creation	2013-03-22 15:17:53
Last modified on	2013-03-22 15:17:53
Owner	matte (1858)
Last modified by	matte (1858)
Numerical id	5
Author	matte (1858)
Entry type	Theorem
Classification	msc 54B05