Pure analytical solutions are not acceptable and the paper must bring a new knowledge at the computational orientation of the work.

 

TOPICS

  1. Static and Quasi-static Fields: Electrostatics, Magnetostatics, Eddy Currents.
  2. Wave Propagation: Scattering, Radiation, Microwaves, Antennas, Waveguide, FDTD Methods, Integral Methods, TLM.
  3. Electromagnetic Compatibility: Emission and immunity, Absorption materials, Computational methods, High power electromagnetics, ESD, Crosstalk, Shielding, Wired & wireless communications, EMC management, PCB, Signal integrity.
  4. Material Modeling: Magnetic materials, Superconducting Materials, Composite Materials, Metamaterials, Intelligent Reconfigurable Surfaces (IRS), Graphene applications, Hysteresis and Anisotropy, Permanent Magnets, Magnetostrictive or Piezoelectric Materials, Microwave Absorbing Materials, Ab-initio Quantum Mechanical Modeling, Nondestructive Testing.
  5. Coupled Problems: Mechanical Problems, Plasma problems, Electric Circuits, Thermal Problems.
  6. Numerical Techniques: Computational electromagnetics, High-frequency and asymptotic methods, FEM methods, Finite volumes, spectral methods, discontinuous Galerkin methods, meshless methods, Nonlinear Problems, Parallel and Distributed Computing, Methods for solving large systems, Multiscale Modeling, Uncertainty Quantification and Sensitivity Analysis.
  7. Optimization and Design: Shape and Topological Optimization, Stochastic and Hybrid Techniques, Multi-Objective and Multi-Level Optimization, Robust Optimization under Uncertainty, Inverse Problems, Sensitivity Analysis, Deterministic Methods.
  8. Machine Learning applied to electromagnetics: Data-driven methods, Digital Twins, Supervised and Unsupervised Learning, Deep learning methods, Artificial Intelligence and Expert Systems, Neural Networks.
  9. Software Methodology: Software Design, Software Engineering and Software Quality, Computer Graphics and Data Representation, Human-Machine Interface.
  10. Nanomagnetics: Spintronics, Nanomagnetics Modeling, Magnetic Recording, MRAM, Micromagnetics.
  11. Photonics: Nanophotonics, Plasmonics, Metasurfaces, Microwave and THz photonics, Electro-optics and Semiconductor photonics, Non-linear and 2D-material photonics, Computational photonics and Inverse design, imaging and spectroscopy.
  12. Bioelectromagnetic Fields Computation: Numerical Approximation, Geometric Modeling and Scientific Visualization (Human Body), Integrated Software Environments, Biomedical Signal Processing, Biomedical devices.
  13. Devices and Applications: Electric Machines and Drives, Induction Heating, Power Electronics Devices, MEMS, NEMS, Wireless power transfer, Charged Particles Trajectories, Accelerators, Electromagnetic Launchers, Fusion Machines, Microsystems, Others.
  14. Education