Finite-Difference Time-Domain (FDTD) methods have become a cornerstone in the numerical solution of Maxwell’s equations, enabling detailed electromagnetic analysis across a wide range of applications.

Developed a CUDA version of the FDTD method and achieved a speedup 40x. Implemented on a NVIDIA Quadro FX 3800 GPU, which has 192 SPs, 1GB global memory, and a memory bandwidth of 51.2 GB/s.

Finite-Difference Time-Domain (FDTD) methods have long served as a workhorse for simulating electromagnetic wave propagation. In dispersive media, where material responses vary with frequency, the ...

Allen Taflove, professor of electrical and computer engineering at Northwestern Engineering who conducted pioneering work in the finite-difference time-domain (FDTD) method, passed away at age 71 on ...

Prof. Allen Taflove is featured in the most-recent issue of Nature Photonics (January 2015, Volume 9 No 1 pp1-72) for his pioneering work in computational electromagnetics, specifically the Finite ...

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