Inovative Electromagnetic Systems

Data is displayed for the academic year: 2024./2025.

Exercises

Laboratory exercises

Course Description

Artificial EM structures, matamaterials, and metasurfaces. Constraints of passive EM structures, dispersion equations, Foster's theorem. Active EM structures, non-Foster structures, time-varying structures. Design, manufacturing, and measurements of a prototype of EM system with active and passive EM structures.

Study Programmes

University graduate
[FER3-HR] Audio Technologies and Electroacoustics - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Communication and Space Technologies - profile
Elective Courses (1. semester) (3. semester)
Elective Courses of the Profile (1. semester) (3. semester)
[FER3-HR] Computational Modelling in Engineering - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Computer Engineering - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Computer Science - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Control Systems and Robotics - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Data Science - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Electrical Power Engineering - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Electric Machines, Drives and Automation - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Electronic and Computer Engineering - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Electronics - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Information and Communication Engineering - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Network Science - profile
Elective Courses (1. semester) (3. semester)
[FER3-HR] Software Engineering and Information Systems - profile
Elective Courses (1. semester) (3. semester)

Learning Outcomes

  1. Analysis of passive artificial EM structures
  2. Analysis of active EM structures
  3. Design of passive artificial EM structures
  4. Design of active artificial EM structures
  5. Design of entire EM system tha comprises both passive and active EM structures

Forms of Teaching

Lectures

--

Independent assignments

--

Laboratory

--

Work with mentor

--

Week by Week Schedule

  1. Separation of variables
  2. Auxiliary potentials
  3. Analysis of waveguides and resonant structures
  4. Analysis of waveguides and resonant structures
  5. Analysis of waveguides and resonant structures, Finite difference time domain (FDTD) method and finite integral technique (FIT)
  6. Analysis of waveguides and resonant structures, Integral equations; Green functions, Application of finite element method in electromagnetics
  7. Integral equations; Green functions, Mode matching method
  8. Midterm exam, Finite difference time domain (FDTD) method and finite integral technique (FIT)
  9. Application of finite element method in electromagnetics
  10. Application of moment method in antenna analysis
  11. High frequency methods (ray-tracing, uniform theory of diffraction)
  12. Plasmonic waveguides; Plasmonic structures for scattering of electromagnetic energy; Plasmonic antennas
  13. Plasmonic waveguides; Plasmonic structures for scattering of electromagnetic energy; Plasmonic antennas
  14. Graphene; Surface impedance; Equivalent permittivity and permeability
  15. Final exam

Literature

N. Engheta and R. Ziolkowski (editors) (2006.), Metamaterials, Physics and Engineering Explorations, John Wiley and IEEE Press
C. A. Balanis (2012.), Advanced Engineering Electromagnetic, Wiley
W. L. Stutzmann and G. A. Thiele (2013.), Antenna Theory and Design, Wiley
A. Taflove and S.C. Hagness (2005.), Computational Electrodynamics:The Finite-Difference Time-Domain Method, Artech House

For students

General

ID 222559
  Winter semester
5 ECTS
L3 English Level
L1 e-Learning
30 Lectures
0 Seminar
15 Exercises
6 Laboratory exercises
0 Project laboratory
0 Physical education excercises

Grading System

Excellent
Very Good
Good
Sufficient