AbstractThe purpose of this paper is to show how the problem of finding roots (or zeros) of the monic quaternionic quadratic polynomials (MQQP) can be solved by its equivalent real quadratic form. The real quadratic form matrices, firstly defined in this paper, are used to form a simple equivalent real quadratic form of MQQP. Some necessary and sufficient conditions for the existence of roots of MQQP are also presented. The main idea of the practical method proposed in this work can be summarized in two steps: translating MQQP into its equivalent real quadratic form, and giving directly the quaternionic roots of MQQP by solving its equivalent real quadratic form
The scalar-vector representation is used to derive a simple algorithm to obtain the roots of a quadr...
In this paper we propose a version of Newton method for finding zeros of a quaternion function of a...
In this project, we introduce Python code for solving Quaternionic Quadratic Equations(QQE). Liping ...
AbstractThe purpose of this paper is to show how the problem of finding roots (or zeros) of the moni...
AbstractIn this paper, we derive explicit formulas for computing the roots of a quaternionic quadrat...
The purpose of this paper is to show how the problem of finding the zeros of unilateral n-order quat...
In this paper we focus on the study of monic polynomials whose coefficients are quaternions located ...
AbstractA method is developed to compute the zeros of a quaternion polynomial with all terms of the ...
This article explores the numerical mathematics and visualization capabilities of Mathematica in the...
We revisit the quaternion Newton method for computing roots of a class of quaternion valued function...
In this paper we revisit the ring of (left) one-sided quaternionic polynomials with special focus on...
A method is developed to compute the zeros of a quaternion polynomial with all terms of the form qkX...
A method is proposed with which the locations of the roots of the monic symbolic quintic polynomial ...
In this paper we determine the sets of spherical roots, real roots, isolated complex roots, pure im...
This paper aims to present, in a unified manner, results which are valid on both the algebras of qua...
The scalar-vector representation is used to derive a simple algorithm to obtain the roots of a quadr...
In this paper we propose a version of Newton method for finding zeros of a quaternion function of a...
In this project, we introduce Python code for solving Quaternionic Quadratic Equations(QQE). Liping ...
AbstractThe purpose of this paper is to show how the problem of finding roots (or zeros) of the moni...
AbstractIn this paper, we derive explicit formulas for computing the roots of a quaternionic quadrat...
The purpose of this paper is to show how the problem of finding the zeros of unilateral n-order quat...
In this paper we focus on the study of monic polynomials whose coefficients are quaternions located ...
AbstractA method is developed to compute the zeros of a quaternion polynomial with all terms of the ...
This article explores the numerical mathematics and visualization capabilities of Mathematica in the...
We revisit the quaternion Newton method for computing roots of a class of quaternion valued function...
In this paper we revisit the ring of (left) one-sided quaternionic polynomials with special focus on...
A method is developed to compute the zeros of a quaternion polynomial with all terms of the form qkX...
A method is proposed with which the locations of the roots of the monic symbolic quintic polynomial ...
In this paper we determine the sets of spherical roots, real roots, isolated complex roots, pure im...
This paper aims to present, in a unified manner, results which are valid on both the algebras of qua...
The scalar-vector representation is used to derive a simple algorithm to obtain the roots of a quadr...
In this paper we propose a version of Newton method for finding zeros of a quaternion function of a...
In this project, we introduce Python code for solving Quaternionic Quadratic Equations(QQE). Liping ...