Multiplicative Regular Representations of Units of Topological Ring are Homeomorphisms

Theorem
Let $\struct{R, +, \circ, \tau}$ be a topological ring with unity $1_R$.

For all $y \in R$, let $\lambda_y$ and $\rho_y$ denote the left and right regular representations of $\struct{R, \circ}$ with respect to $y$.

Let $x \in R$ be a unit of $R$ with product inverse $x^{-1}$.

Then $\,\lambda_x, \,\rho_x : \struct{R, \tau} \to \struct{R, \tau}$ are homeomorphisms with inverse mappings $\,\lambda_{x^{-1}}, \,\rho_{x^{-1}}  : \struct{R, \tau} \to \struct{R, \tau}$ respectively.

Proof
Let $\iota_{_R} : R \to R$ be the identity mapping on $R$.

For all $y \in R$, let $y * \iota_{_R}, \iota_{_R} * y$ denote the left and right scalar multiples of $\iota_{_R}$ by $y$.

Lemma 1
From Identity Mapping is Continuous, $\iota_{_R} : \struct{R, \tau} \to \struct{R, \tau}$ is continuous.

From Multiple Rule for Continuous Mappings of Topological Ring:
 * $x * \iota_{_R}, \,\iota_{_R} * x, x^{-1} * \iota_{_R}, \,\iota_{_R} * x^{-1}$ are continuous.

Lemma 2
By definition of homeomorphism, $\,\lambda_x, \,\rho_x : \struct{R, \tau} \to \struct{R, \tau}$ are homeomorphisms with inverse mappings $\,\lambda_{x^{-1}}, \,\rho_{x^{-1}}  : \struct{R, \tau} \to \struct{R, \tau}$ respectively.