Graph of Continuous Mapping is Homeomorphic to Domain

Theorem
Let $T_1$ and $T_2$ be topological spaces.

Let $f$ be a homeomorphism from $T_1$ to $T_2$.

Let $G_f$ denote the graph of $f$.

Then $f$ is homeomorphic to $G_f$.

Prooof
Let $\iota: G_f \to T_1 \times T_2$ be the inclusion mapping from $G_f$ into $T_1 \times T_2$.

Let $\theta: G_f \to T_1$ and $\psi: T_1 \to G_f$ be given by:


 * $\theta = \pr_1 \circ \iota$


 * $\forall x \in T_1: \map \psi x = \tuple {x, \map f x}$

$\theta$ and $\psi$ are seen to be inverses of each other.

The fact that $\theta$ is continuous follows from the fact that $\pr_1$ and $\iota$ are both continuous.

Then $\pr_1 \circ \iota \circ \psi$ is the identity mapping on $T_1$ and so is continuous.

Also, $\pr_2 \circ \iota \circ psi$ is also continuous.

Hence by Continuous Mapping to Product Space, $\iota \circ \psi$ is continuous.

It follows by Continuity of Composite with Inclusion/Inclusion on Mapping that $\psi$ is continuous.