This course will cover the fundamental concepts of electromagnetics, focusing on static electric and magnetic phenomena. You will learn techniques to solve various electrostatic and magnetostatic problems, as well as their real-world applications. Maxwell's equations will also be covered.
This course will cover the fundamental concepts of microwave and millimeter-wave circuit design, the operating principles of key components based on these concepts, and their applications in modern wireless systems. Students will learn network analysis techniques for the design and characterization of high-frequency circuits, along with essential knowledge for their experimental characterization. Through software projects, students will gain hands-on experience in designing microwave passive components using numerical simulation tools.
In this course, the fundamental concepts of electromagnetic radiation, the operating principles of various antennas utilizing these concepts, and the methods for antenna design will be covered. Also, you will learn key antenna parameters used to characterize antennas and acquire the knowledge needed for the analysis and measurement of antennas. Furthermore, a brief introduction to recent progress in antenna research will be provided. Through design projects, you will be required to learn the antenna design process using full-wave electromagnetic solvers.
Graduate-level course on advanced topics in applied electrodynamics, metamaterials, and metasurfaces. Topics include the optical/electromagnetic properties of materials; Clausius-Mossotti relation; causality and Kramers-Kronig relations; wave propagation in complex media and periodic structures; The course also introduces several topics on recent research progress in the field of metamaterials/metasurfaces as well as applications to electromagnetic and optical devices.
Transformation optical cloak
Negative index material and surface wave
Gradient index (GRIN) lens
Graduate-level course on advanced topics in applied electrodynamics with a focus on metamaterials and metasurfaces, emphasizing their theoretical foundations and practical design techniques. Topics include the electromagnetic theory of metasurfaces, holographic pattern synthesis, coupled dipole modeling framework, the method of moments (MoM), and numerical optimization techniques.