GPU-based three-dimensional calculation of lightning-generated electromagnetic fields

“…induced disturbances on nearby structures, such as overhead transmission lines and buried cables (e.g., [25][26][27][28][29][30][31]), computations have been carried out by making use of CPU-based systems. However, there exist several attempts in which different hardware platforms have been used for the same study (e.g., [32][33][34][35][36]). One example is the use of GPU-based compute unified device architecture (CUDA) programming for the finite difference time domain (FDTD) evaluation of lightning electromagnetic fields.…”

“…Recently, graphical processing using OpenACC has caught the attention of many researchers due to its relative simplicity and high performance (e.g., [39,40]). One of the particular examples of using OpenACC on graphics processors is to calculate the vector potential using the finite difference generated by time-domain However, there exist several attempts in which different hardware platforms have been used for the same study (e.g., [32][33][34][35][36]). One example is the use of GPU-based compute unified device architecture (CUDA) programming for the finite difference time domain (FDTD) evaluation of lightning electromagnetic fields.…”

“…One example is the use of GPU-based compute unified device architecture (CUDA) programming for the finite difference time domain (FDTD) evaluation of lightning electromagnetic fields. Due to its high-speed calculation, this approach facilitates three-dimensional modeling of a problem, taking into account parameter uncertainties such as irregular lightning channel and surface roughness [34]. It is noted that this approach is supposedly 100 times faster than the serial processing approach in CPU [33].…”

On the Efficiency of OpenACC-aided GPU-Based FDTD Approach: Application to Lightning Electromagnetic Fields

“…induced disturbances on nearby structures, such as overhead transmission lines and buried cables (e.g., [25][26][27][28][29][30][31]), computations have been carried out by making use of CPU-based systems. However, there exist several attempts in which different hardware platforms have been used for the same study (e.g., [32][33][34][35][36]). One example is the use of GPU-based compute unified device architecture (CUDA) programming for the finite difference time domain (FDTD) evaluation of lightning electromagnetic fields.…”

“…Recently, graphical processing using OpenACC has caught the attention of many researchers due to its relative simplicity and high performance (e.g., [39,40]). One of the particular examples of using OpenACC on graphics processors is to calculate the vector potential using the finite difference generated by time-domain However, there exist several attempts in which different hardware platforms have been used for the same study (e.g., [32][33][34][35][36]). One example is the use of GPU-based compute unified device architecture (CUDA) programming for the finite difference time domain (FDTD) evaluation of lightning electromagnetic fields.…”

“…One example is the use of GPU-based compute unified device architecture (CUDA) programming for the finite difference time domain (FDTD) evaluation of lightning electromagnetic fields. Due to its high-speed calculation, this approach facilitates three-dimensional modeling of a problem, taking into account parameter uncertainties such as irregular lightning channel and surface roughness [34]. It is noted that this approach is supposedly 100 times faster than the serial processing approach in CPU [33].…”

On the Efficiency of OpenACC-aided GPU-Based FDTD Approach: Application to Lightning Electromagnetic Fields

GPU-Based Calculation of Lightning-Generated Electromagnetic Fields in 3-D Problems With Statistically Defined Uncertainties

A real-time big data analysis framework on a CPU/GPU heterogeneous cluster