Accelerating Electromagnetic Field Simulations Based on Memory-Optimized CPML-FDTD with OpenACC

Padilla-Pérez, Diego; Medina, I.; Hernández-Gómez, J. J.; Couder-Castañeda, Carlos

doi:10.3390/app122211430

Cited by 3 publications

(1 citation statement)

References 38 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The computation in the CPML regions is likewise incorporated into the kernels updating the H and E fields. Other implementations either expand the CPML region to whole domain and assign zero values at the non-boundary regions [32], [33] or update the CPML regions into multiple independent kernels [33], [34]. The first approach increases unnecessarily the memory requirements.…”

Section: Fdtd Solver Design and Kernel Optimizationsmentioning

confidence: 99%

Accelerated Medical Microwave Tomography via Heterogeneous Computing

Vasileiou,

Kosmas

2024

Preprint

View full text Add to dashboard Cite

Implementation of three-dimensional (3D) numerical electromagnetic (EM) inverse scattering algorithms has been limited for over two decades due to the huge computational cost in practical applications such as medical microwave imaging. The emergence of graphics processing units (GPU) computing has offered new possibilities for alleviating the computational burden related to EM computations, but its optimized deployment for EM inverse scattering has not been explored. We present a suite of optimization strategies towards this aim, and study their impact on computational savings in different computing platforms. Our results demonstrate the significance of incorporating the solution of the inverse problem on heterogeneous systems. By combining these strategies in an optimal way, we arrive at imaging times of half a minute for iterative microwave tomography (MWT) problems involving eight antennas and hundreds thousands of reconstructed voxels in simulation domains of over 1 million voxels.

show abstract

Section: Fdtd Solver Design and Kernel Optimizationsmentioning

confidence: 99%

Accelerated Medical Microwave Tomography via Heterogeneous Computing

Vasileiou,

Kosmas

2024

Preprint

View full text Add to dashboard Cite

show abstract

Optimizing hybrid neural networks for precise COVID-19 mRNA vaccine degradation prediction

Soon,

Abdullah,

Nishizaki

et al. 2024

Int. j. adv. appl. sci.

View full text Add to dashboard Cite

Conventional hybrid models often miss an essential factor that can lead to less effective performance: intrinsic sequence dependence when combining various neural network (NN) architectures. This study addresses this issue by highlighting the importance of sequence hybridization in NN architecture integration, aiming to improve model effectiveness. It combines NN layers—dense, long short-term memory (LSTM), and gated recurrent unit (GRU)—using the Keras Sequential API for defining the architecture. To provide better context, bidirectional LSTM (BiLSTM) and bidirectional GRU (BiGRU) replace their unidirectional counterparts, enhancing the models through bidirectional structures. Out of 25 NN models tested, 18 four-layer hybrid NN models consist of one-quarter dense layer and the rest BiLSTM and BiGRU layers. These hybrid NN models undergo supervised learning regression analysis, with mean column-wise root mean square error (MCRMSE) as the performance metric. The results show that each hybrid NN model produces unique outcomes based on its specific hybrid sequence. The Hybrid_LGSS model performs better than existing three-layer BiLSTM networks in predictive accuracy and shows lower overfitting (MCRMSEs of 0.0749 and 0.0767 for training and validation, respectively). This indicates that the optimal hybridization sequence is crucial for achieving a balance between performance and simplicity. In summary, this research could help vaccinologists develop better mRNA vaccines and provide data analysts with new insights for improvement.

show abstract

Scattering and Attenuation in 5G Electromagnetic Propagation (5 GHz and 25 GHz) in the Presence of Rainfall: A Numerical Study

Yáñez-Casas,

Couder-Castañeda,

Hernández-Gómez

et al. 2023

Mathematics

Self Cite

View full text Add to dashboard Cite

Rainfall has always been a concern for wireless communications systems. As 5G technology relies on high-frequency bands, it is fundamental to model and simulate the interaction of such radio waves with rainfall, as the deployment of large-scale infrastructure for 5G is highly expensive. This research presents a reformulation of the Maxwell equations for a bi-dimensional space in a transverse electric propagation mode, for a linear, inhomogeneous, and isotropic propagation medium with its magnetic and electric properties dependent on time. This reformulation was solved using the Finite Differences in Time Domain (FDTD) method with the Convolutional Perfectly Matched Layer (CPML) boundary condition. Two main frequency propagation scenarios were studied: 5 GHz (corresponding to Wi-Fi in the 802.11n standard as well as to the lowest bands of 5G) and 25 GHz (corresponding to 5G), within a 10m×3m rectangular domain in air and with rain. The rainfall was simulated using a parallel Ziggurat algorithm. According to the findings, while 5 GHz waves experience scattering processes, 25 GHz waves experience substantial dispersion and attenuation throughout the domain in low- to moderate-intensity rain.

show abstract

Accelerating Electromagnetic Field Simulations Based on Memory-Optimized CPML-FDTD with OpenACC

Cited by 3 publications

References 38 publications

Accelerated Medical Microwave Tomography via Heterogeneous Computing

Accelerated Medical Microwave Tomography via Heterogeneous Computing

Optimizing hybrid neural networks for precise COVID-19 mRNA vaccine degradation prediction

Scattering and Attenuation in 5G Electromagnetic Propagation (5 GHz and 25 GHz) in the Presence of Rainfall: A Numerical Study

Contact Info

Product

Resources

About