Let $H$ be the quaternions algebra. An $H^{*}$ algebra is a normed ring $A$ which is simultaneously a unital  left $H$ module and has an involution $*$ with the following properties:


$\forall \lambda \in H, a,b \in A$ 



1.$\;\lambda(ab)=(\lambda a)b$  


2. $\; \parallel ab\parallel \leq  \parallel a \parallel \parallel b \parallel$

3. $\;(ab)^{*}=b^{*}a^{*}$


4.$\;\;\parallel ab\parallel \leq \parallel a \parallel \parallel b \parallel$ 

5.  $\;\; \parallel aa^{*} \parallel= \parallel a  \parallel^{2}$

There is  a natural definition of spectrum of an element $a\in A$ (as a subset of $H$). There is also a natural definition of morphism and isomorphisms between two $H^{*}$ algebras.

**Example:** For  a  compact Hausdorff space $X$ put $A=H(X)=$ The space of all continuous  $f:X \to H$ with obvious structures

**Questions:**
> 1. Is it true to say that the spectrum is always  non empty and compact?

>2. Is it true to say that two compact space $X$ and $Y$ are homeomorphic if and only if $H(X) \simeq H(Y)$?


The motivation for this question is that we search for an alternative proof for the Borsuk Ulam  theorem for $f;S^{4} \to \mathbb{R}^{4} \simeq H$ via consideration of  a $\mathbb{Z}/2\mathbb{Z}$ graded structure for $H(S^{4})$. see the following related  post

http://mathoverflow.net/questions/218679/banach-algebraic-proof-of-the-borsuk-ulam-theorem/221210#221210