Fundamentals of Electromagnetics
This course introduces electromagnetic principles and describes how they are applied in engineering devices and systems. Topics include: vector calculus, Maxwell’s equations in integral and differential forms with associated boundary conditions, quasi static electric fields in free space and in materials, superposition for known charge sources, conduction and polarization, resistance and capacitance, charge relaxation, analytic and numerical methods for electric field boundary value problems, quasi static magnetic fields in free space and in materials, superposition for known current sources, magnetization, inductance, magnetic diffusion, and analytic and numerical methods for magnetic field boundary value problems.
Identify, formulate, and solve complex engineering problems by
applying engineering fundamentals, basic science and mathematics.
Develop and conduct appropriate experimentation and/or simulation,
analyze and interpret data, assess and evaluate findings, and use
statistical analyses and objective engineering judgment to draw
conclusions.Communicate effectively – graphically, verbally and in writing – with
a range of audiences using contemporary tools.Design, model and analyze an electrical, electronic, microwave and
optical system or component for a specific ICT application and
identify the tools required to optimize this design.Understand the key principles of signal processing, control theory,
and the main components of analog and digital communication
systems. As well as, DSP and embedded systems