Recent Courses
- EE345, Electromagnetics: Electrostatics and magnetics; induced electro-motive force; Maxwell equations and their physical interpretation and application; Transmission lines; Radiation and antennas
- EE442, Microwave engineering (I) - passive components: Transmission line theory and application, wave propagation in rectangular waveguides, microwave network analysis, matching network, design of microwave filter and resonator, and introduction of electromagnetic compatibility.
- EE445, Electromagnetic compatibility, Identification of possible sources of electromagnetic interference (EMI) in an electronic device or system. Fundamental EMC design principles concerning conducted and radiated emissions, reduction of susceptibility to EMI and EMI shielding.
- EE446, Microwave engineering (II) - active components and circuits, Fundamental of RF active components; Modeling of RF active components; Design impedance matching network; Microwave transistor amplifier design; Microwave transistor oscillator and mixer design; Introduction to microwave systems
- EE447, Antennas, Linear dipole antennas, antenna arrays, thin-wire antennas, moment method analysis examples (vee dipole, folded dipole, etc.), and broadband and frequency-independent antennas. Computer-aided design and analysis of wire antennas, feed networks, and antenna arrays using antenna CAD software.
- EE480, Microfabrication engineering for VLSI and MEMs, Principles of CMOS fabrication processes. Technological limitations of integrated circuits design. Topics include bulk crystal and epitaxial growth, thermal oxidation, diffusion, ion-implantation, chemical vapor deposition, dry etching, lithography, and metallization. Topics also include the state-of-the-art modern Si technology, such as SOI and SON. MEMs technology will be discussed at the introductory level and focused on RF-MEMs.