AbstractWe present an asymptotically derived boundary element method for the Helmholtz equation in exterior domains. Each basis function is the product of a smooth amplitude and an oscillatory phase factor, like the asymptotic solution. The phase factor is determined a priori by using arguments from geometrical optics and the geometrical theory of diffraction, while the smooth amplitude is represented by high-order splines. This yields a high-order method in which the number of unknowns is virtually independent of the wavenumber k. Two types of diffracted basis functions are presented: the first accounts for the dominant oscillatory behavior in the shadow region while the second also accounts for the decay of the amplitude there. We show th...
AbstractIt is often noted that the Helmholtz equation is extremely difficult to solve, in particular...
We consider two-dimensional scattering problems, formulated as an integral equation defined on the b...
Over the last ten years, results from [48], [49], [22], and [47] decomposing high-frequency Helmholt...
In this article we describe recent progress on the design, analysis and implementation of hybrid num...
In this thesis several aspects of the Partition of Unity Boundary Element Method (PUBEM) are investi...
In this paper we use an enriched approximation space for the efficient and accurate solution of the ...
In this article we review recent progress on the design, analysis and implementation of numerical-as...
This is a post-peer-review, pre-copyedit version of an article published in Numerische Mathematik. T...
Wave propagation and acoustic scattering problems require vast computational resources to be solved ...
Paper presented at the 3rd Strathmore International Mathematics Conference (SIMC 2015), 3 - 7 August...
It is often noted that the Helmholtz equation is extremely difficult to solve, in particular, for hi...
This chapter presents the application of the boundary element method to high-frequency Helmholtz pro...
The discretisation of boundary integral equations for the scalar Helmholtz equation leads to large d...
In this thesis, we will investigate and develop asymptotic methods for numerically solving high freq...
We present a novel hybrid numerical–asymptotic boundary element method for high frequency acoustic a...
AbstractIt is often noted that the Helmholtz equation is extremely difficult to solve, in particular...
We consider two-dimensional scattering problems, formulated as an integral equation defined on the b...
Over the last ten years, results from [48], [49], [22], and [47] decomposing high-frequency Helmholt...
In this article we describe recent progress on the design, analysis and implementation of hybrid num...
In this thesis several aspects of the Partition of Unity Boundary Element Method (PUBEM) are investi...
In this paper we use an enriched approximation space for the efficient and accurate solution of the ...
In this article we review recent progress on the design, analysis and implementation of numerical-as...
This is a post-peer-review, pre-copyedit version of an article published in Numerische Mathematik. T...
Wave propagation and acoustic scattering problems require vast computational resources to be solved ...
Paper presented at the 3rd Strathmore International Mathematics Conference (SIMC 2015), 3 - 7 August...
It is often noted that the Helmholtz equation is extremely difficult to solve, in particular, for hi...
This chapter presents the application of the boundary element method to high-frequency Helmholtz pro...
The discretisation of boundary integral equations for the scalar Helmholtz equation leads to large d...
In this thesis, we will investigate and develop asymptotic methods for numerically solving high freq...
We present a novel hybrid numerical–asymptotic boundary element method for high frequency acoustic a...
AbstractIt is often noted that the Helmholtz equation is extremely difficult to solve, in particular...
We consider two-dimensional scattering problems, formulated as an integral equation defined on the b...
Over the last ten years, results from [48], [49], [22], and [47] decomposing high-frequency Helmholt...