We show the efficacy of graphics hardware for the computational electrodynamics community. In particular, we illustrate how this hardware can be used to accelerate a general purpose Finite-Difference Time-Domain (FDTD) simulation through a set of image processing operations. While achieving a significant speedup, our simulation yields comparable accuracy to that of a consonant software implementation
Finite-Difference Time-Domain (FDTD) is a popular technique for modeling computational electrodynami...
A number of inherent characteristics makes the Finite Difference Time Domain (FDTD) algorithm almost...
The analysis of high-field RF fieldtissue interactions requires high-performance finite-difference t...
International audienceAmong the techniques widely used in CEM (Computational Electromagnetics), the ...
Abstract:- Our group has employed the use of modern graphics processor units (GPUs) for the accelera...
Traditionally, optical circuit design is tested and validated using software which implement numeric...
The recent advent of general-purpose graphics-processing units (GPGPUs) as inexpensive arithmetic-pr...
When creating electronic devices, it is essential to model what happens when an electromagnetic fiel...
In the field of electromagnetic modeling, whether it is the complex designs for engineered materials...
The continued development of improved algorithms and architecture for numerical simulations is at th...
Abstract—This paper presents an implementation of the FDTD-compatible Green’s function on a heteroge...
Abstract: An implementation of FDTD (Finite Difference Time Domain) method for solution of...
The finite difference time domain (FDTD) method is a popular technique for computational electromagn...
Abstract—The programmable graphics processing unit (GPU) is employed to accelerate the unconditional...
Electromagnetics, which govern the fields of wireless communications, radar, and remote sensing, are...
Finite-Difference Time-Domain (FDTD) is a popular technique for modeling computational electrodynami...
A number of inherent characteristics makes the Finite Difference Time Domain (FDTD) algorithm almost...
The analysis of high-field RF fieldtissue interactions requires high-performance finite-difference t...
International audienceAmong the techniques widely used in CEM (Computational Electromagnetics), the ...
Abstract:- Our group has employed the use of modern graphics processor units (GPUs) for the accelera...
Traditionally, optical circuit design is tested and validated using software which implement numeric...
The recent advent of general-purpose graphics-processing units (GPGPUs) as inexpensive arithmetic-pr...
When creating electronic devices, it is essential to model what happens when an electromagnetic fiel...
In the field of electromagnetic modeling, whether it is the complex designs for engineered materials...
The continued development of improved algorithms and architecture for numerical simulations is at th...
Abstract—This paper presents an implementation of the FDTD-compatible Green’s function on a heteroge...
Abstract: An implementation of FDTD (Finite Difference Time Domain) method for solution of...
The finite difference time domain (FDTD) method is a popular technique for computational electromagn...
Abstract—The programmable graphics processing unit (GPU) is employed to accelerate the unconditional...
Electromagnetics, which govern the fields of wireless communications, radar, and remote sensing, are...
Finite-Difference Time-Domain (FDTD) is a popular technique for modeling computational electrodynami...
A number of inherent characteristics makes the Finite Difference Time Domain (FDTD) algorithm almost...
The analysis of high-field RF fieldtissue interactions requires high-performance finite-difference t...