Abstract. We describe an accelerated direct solver for the integral equations which model acoustic scat-tering from curved surfaces. Surfaces are specified via a collection of smooth parameterizations given on triangles, a setting which generalizes the typical one of triangulated surfaces, and the integral equations are discretized via a high-order Nyström method. This allows for rapid convergence in cases in which high-order surface information is available. The high-order discretization technique is coupled with a di-rect solver based on the recursive construction of scattering matrices. The result is a solver which often attains O(N1.5) complexity in the number of discretization nodes N and which is resistant to many of the pathologies ...
We consider the approximation of some highly oscillatory weakly singular surface integrals, arising ...
We describe a fully discrete high-order algorithm for simulating low to medium frequency electromagn...
We present an accurate method of O(1)-complexity with respect to frequency (i.e., a method that, to ...
We present a new algorithm for the numerical solution of problems of acoustic scatter-ing by surface...
We present a new algorithm for the numerical solution of problems of acoustic scattering by surfaces...
We present a fast, high-order algorithm for the solution of problems of acoustic scattering from smo...
We present a new algorithm for the numerical solution of problems of acoustic scattering by surfaces...
We review a set of algorithms and methodologies developed recently for the numerical solution of pro...
We review a new set of algorithms and methodologies for the numerical solution of problems of scatte...
This paper presents a high-order accelerated algorithm for the solution of the integral-equation for...
We propose a numerical surface integral method to study complex acoustic systems, for interior and e...
The acoustic scattering off curved bodies is computed, using a CAA-code which implements the DRP-sch...
We present an accelerated and hardware parallelized integral-equation solver for the problem of acou...
We present a new set of high-order algorithms and methodologies for the numerical solution of proble...
This text proposes a fast, rapidly convergent Nyström method for the solution of the Lippmann–Schwin...
We consider the approximation of some highly oscillatory weakly singular surface integrals, arising ...
We describe a fully discrete high-order algorithm for simulating low to medium frequency electromagn...
We present an accurate method of O(1)-complexity with respect to frequency (i.e., a method that, to ...
We present a new algorithm for the numerical solution of problems of acoustic scatter-ing by surface...
We present a new algorithm for the numerical solution of problems of acoustic scattering by surfaces...
We present a fast, high-order algorithm for the solution of problems of acoustic scattering from smo...
We present a new algorithm for the numerical solution of problems of acoustic scattering by surfaces...
We review a set of algorithms and methodologies developed recently for the numerical solution of pro...
We review a new set of algorithms and methodologies for the numerical solution of problems of scatte...
This paper presents a high-order accelerated algorithm for the solution of the integral-equation for...
We propose a numerical surface integral method to study complex acoustic systems, for interior and e...
The acoustic scattering off curved bodies is computed, using a CAA-code which implements the DRP-sch...
We present an accelerated and hardware parallelized integral-equation solver for the problem of acou...
We present a new set of high-order algorithms and methodologies for the numerical solution of proble...
This text proposes a fast, rapidly convergent Nyström method for the solution of the Lippmann–Schwin...
We consider the approximation of some highly oscillatory weakly singular surface integrals, arising ...
We describe a fully discrete high-order algorithm for simulating low to medium frequency electromagn...
We present an accurate method of O(1)-complexity with respect to frequency (i.e., a method that, to ...