#### Volume 46, pp. 55-70, 2017.

## The number of zeros of unilateral polynomials over coquaternions and related algebras

Drahoslava Janovská and Gerhard Opfer

### Abstract

We have proved that unilateral polynomials over the nondivision
algebras in $\mathbb{R}^4$
have at most
$n(2n-1)$ zeros, when the polynomial has degree $n$. Moreover, we have created an algorithm
for finding all zeros of polynomials over these algebras using a real polynomial of degree $2n$,
called *companion polynomial*. The algebras in question are coquaternions, $\mathbb{H}_{\rm coq}$,
nectarines, $\mathbb{H}_{\rm nec}$, and conectarines, $\mathbb{H}_{\rm con}$. Besides the isolated and hyperbolic zeros
we introduce a new type of zeros, the *unexpected* zeros.
There is a formal algorithm, and there are numerical examples.
In a tutorial section on similarity we show how to find the similarity transformation of
two algebra elements
to be known as similar, where a singular value decomposition of a
certain real $4\times4$ matrix related
to the two similar elements has to be applied. We show that there is a
strong indication that an algorithm
by Serôdio, Pereira, and Vitória [Comput. Math. Appl., 42 (2001), pp. 1229–1237],
designed for finding zeros of quaternionic polynomials,
is also valid in the nondivision algebras in $\mathbb{R}^4$ and it produces–-though
with another technique–-the same zeros as those proposed in this paper.

Full Text (PDF) [321 KB], BibTeX

### Key words

number of zeros of polynomials over nondivision algebras in $\mathbb{R}^4$, number of zeros of polynomials over coquaternions, number of zeros of polynomials over nectarines, number of zeros of polynomials over conectarines, unexpected zeros, computation of all zeros of polynomials over nondivision algebras in $\mathbb{R}^4$

### AMS subject classifications

12D10, 12E10, 15A66, 1604

### Links to the cited ETNA articles

[11] | Vol. 41 (2014), pp. 133-158 Drahoslava Janovská and Gerhard Opfer: Zeros and singular points for one-sided coquaternionic polynomials with an extension to other $R^4$ algebras |

[16] | Vol. 26 (2007), pp. 82-102 Drahoslava Janovská and Gerhard Opfer: Computing quaternionic roots by Newton's method |

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