AbstractThis paper proposes a parallel solver for the nonlinear systems in Bernstein form based on subdivision and the Newton–Raphson method, where the Kantorovich theorem is employed to identify the existence of a unique root and guarantee the convergence of the Newton–Raphson iterations. Since the Kantorovich theorem accommodates a singular Jacobian at the root, the proposed algorithm performs well in a multiple root case. Moreover, the solver is designed and implemented in parallel on Graphics Processing Unit(GPU) with SIMD architecture; thus, efficiency for solving a large number of systems is improved greatly, an observation validated by our experimental results
Fredholm integral equations of the first kind are known to be ill-posed and may be impossible to sol...
International audienceFinding the roots of polynomials is a very important part of solving real-life...
[[abstract]]In this paper we use hypercube computers for solving linear systems. First, the pivoting...
This paper proposes a parallel solver for the nonlinear systems in Bernstein form based on subdivisi...
AbstractThis paper proposes a parallel solver for the nonlinear systems in Bernstein form based on s...
We present a method for solving arbitrary systems of N nonlinear polynomials in n variables over an ...
International audienceThe tensorial Bernstein basis for multivariate polynomials in n variables has ...
AbstractThis paper presents two parallel algorithms for the solution of a polynomial equation of deg...
Abstract We present a method for solving arbitrary systems of N nonlinear polynomials in n variables...
Certain classes of nonlinear systems of equations, such as polynomial systems, have properties that ...
AbstractThis paper presents a new algorithm for solving a system of polynomials, in a domain of Rn. ...
International audienceThis paper presents a new algorithm for solving a system of polynomials, in a ...
In the late 1970s and the early 1980s, Yuri Matiyasevich actively used his knowledge of engineering ...
AbstractAn algorithm for approximating solutions to differential equations in a modified new Bernste...
International audienceThis paper deals with the numerical solution of financial applications, more s...
Fredholm integral equations of the first kind are known to be ill-posed and may be impossible to sol...
International audienceFinding the roots of polynomials is a very important part of solving real-life...
[[abstract]]In this paper we use hypercube computers for solving linear systems. First, the pivoting...
This paper proposes a parallel solver for the nonlinear systems in Bernstein form based on subdivisi...
AbstractThis paper proposes a parallel solver for the nonlinear systems in Bernstein form based on s...
We present a method for solving arbitrary systems of N nonlinear polynomials in n variables over an ...
International audienceThe tensorial Bernstein basis for multivariate polynomials in n variables has ...
AbstractThis paper presents two parallel algorithms for the solution of a polynomial equation of deg...
Abstract We present a method for solving arbitrary systems of N nonlinear polynomials in n variables...
Certain classes of nonlinear systems of equations, such as polynomial systems, have properties that ...
AbstractThis paper presents a new algorithm for solving a system of polynomials, in a domain of Rn. ...
International audienceThis paper presents a new algorithm for solving a system of polynomials, in a ...
In the late 1970s and the early 1980s, Yuri Matiyasevich actively used his knowledge of engineering ...
AbstractAn algorithm for approximating solutions to differential equations in a modified new Bernste...
International audienceThis paper deals with the numerical solution of financial applications, more s...
Fredholm integral equations of the first kind are known to be ill-posed and may be impossible to sol...
International audienceFinding the roots of polynomials is a very important part of solving real-life...
[[abstract]]In this paper we use hypercube computers for solving linear systems. First, the pivoting...