In this paper, a GPU-accelerated implementation of a three-dimensional full-wave electromagnetic solver for scattering problems is compared, in terms of performances, with a serial CPU implementation of the same method. The achieved speed-up with respect to the serial code is about 13 for medium-size problems. Finally, as an example of application, the described code is used to compute the specific absorption rate of a magnetic resonance imaging radiofrequency birdcage coil in a voxel-based anatomical head model
In this thesis, fast algorithms for solving fields defined by the Helmholtz equation using integral ...
Accurate scatter correction is essential for qualitative and quantitative PET imaging. Until now, sc...
When creating electronic devices, it is essential to model what happens when an electromagnetic fiel...
A hybrid finite element–boundary element method, developed to solve eddy-current problems in the fre...
The finite difference time domain (FDTD) method is a popular technique for computational electromagn...
In this paper, we combine and extend two of our previous works to provide a more complete solution f...
The work in this dissertation primarily focuses on the development of numerical algorithms for elect...
The analysis of high-field RF fieldtissue interactions requires high-performance finite-difference t...
Diffuse optical tomography is an imaging technique, based on evaluation of how light propagates with...
In the field of electromagnetic modeling, whether it is the complex designs for engineered materials...
In this technical note we show the promise of using graphic processing units (GPUs) to accelerate si...
This thesis is part of a larger project in the field of computational microscopy. Its main contribut...
A new step-by-step comprehensive MR physics simulator (MRISIMUL) of the Bloch equations is presented...
Thesis (M. Eng.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Compute...
We introduce a GPU-accelerated finite element forward solver for the computation of light transport ...
In this thesis, fast algorithms for solving fields defined by the Helmholtz equation using integral ...
Accurate scatter correction is essential for qualitative and quantitative PET imaging. Until now, sc...
When creating electronic devices, it is essential to model what happens when an electromagnetic fiel...
A hybrid finite element–boundary element method, developed to solve eddy-current problems in the fre...
The finite difference time domain (FDTD) method is a popular technique for computational electromagn...
In this paper, we combine and extend two of our previous works to provide a more complete solution f...
The work in this dissertation primarily focuses on the development of numerical algorithms for elect...
The analysis of high-field RF fieldtissue interactions requires high-performance finite-difference t...
Diffuse optical tomography is an imaging technique, based on evaluation of how light propagates with...
In the field of electromagnetic modeling, whether it is the complex designs for engineered materials...
In this technical note we show the promise of using graphic processing units (GPUs) to accelerate si...
This thesis is part of a larger project in the field of computational microscopy. Its main contribut...
A new step-by-step comprehensive MR physics simulator (MRISIMUL) of the Bloch equations is presented...
Thesis (M. Eng.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Compute...
We introduce a GPU-accelerated finite element forward solver for the computation of light transport ...
In this thesis, fast algorithms for solving fields defined by the Helmholtz equation using integral ...
Accurate scatter correction is essential for qualitative and quantitative PET imaging. Until now, sc...
When creating electronic devices, it is essential to model what happens when an electromagnetic fiel...