constant functions and continuity

It is easy to see that every constant function between topological spaces is continuous. A converse result is as follows.

Theorem.

Suppose $X$ is path connected and $D$ is a countable discrete topological space. If $f\colon X\to D$ is continuous, then $f$ is a constant function.

Proof.

By this result (http://planetmath.org/FiniteAndCountableDiscreteSpaces) we can assume that $D$ is either $\{1,\ldots,n\}$ , $n\geq 2$ or $\mathbbmss{Z}$ , and these are equipped with the subspace topology of $\mathbbmss{R}$ . Suppose $f(X)$ has at least two distinct elements, say $\alpha,\beta\in\mathbbmss{Z}$ so that

f(x)=\alpha,\quad f(y)=\beta

for some $x,y\in X$ . Since $X$ is path connected there is a continuous path $\gamma\colon[0,1]\to X$ such that $\gamma(0)=x$ and $\gamma(1)=y$ . Then $f\circ\gamma\colon[0,1]\to D$ is continuous. Since $D$ has the subspace topology of $\mathbbmss{R}$ , this result (http://planetmath.org/ContinuityIsPreservedWhenCodomainIsExtended) implies that also $f\circ\gamma\colon[0,1]\to\mathbbmss{R}$ is continuous. Since $f\circ\gamma$ achieves two different values, it achieves uncountably many values, by the intermediate value theorem. This is a contradiction since $f\circ\gamma([0,1])$ is countable. ∎

Title	constant functions and continuity
Canonical name	ConstantFunctionsAndContinuity
Date of creation	2013-03-22 15:17:31
Last modified on	2013-03-22 15:17:31
Owner	mathcam (2727)
Last modified by	mathcam (2727)
Numerical id	12
Author	mathcam (2727)
Entry type	Theorem
Classification	msc 03E20