For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| ECE5912 | Advanced Electromagnetism | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| The topic of this course is the theoretical analysis of electromagnetic wave phenomenon. Organization of this course is as follows. The course begins with brief introduction to Maxwell's equations. Next, wave equations, characteristics of plane waves, waveguides and resonators, and radiation theory are discussed. Several equivalence theorems and the concept of Green's function are explained. Then, solutions of wave equations and scattering are discussed in cartesian, cylindrical, and spherical coordinates respectively. Finally, the techniques of perturbational and variational techniques are introduced. | |||||||||
| ECE5913 | Advanced Signal Processing | 3 | 6 | Major | Master/Doctor | 1-5 | - | No | |
| A survey of techniques for signal processing going beyond Fourier based approaches. Orthogonal transforms such as Walsh and Hadamard. Homomorphic techniques, generalized Wiener filtering, rank order filtering. Model based signal processing including autoregressive and maximum entropy, frequency-time and space-time, emphasis on algorithms and self paced projects are also covered. | |||||||||
| ECE5914 | Advanced Digital Communications | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| Topics include mathematical modeling of communication channels, digital signal design for the efficient information transmission, and optimum receiver design for the recovery of the distorted signals due to channel effects. More specifically, the following topics are introduced: performance analysis of digital modulation/demodulation schemes, signal detection/estimation, and channel coding. In addition, basics of the spread spectrum communications are discussed. | |||||||||
| ECE5915 | Introduction to Solid State Physics | 3 | 6 | Major | Master/Doctor | 1-5 | - | No | |
| Solid State Physics is concerned with the properties, often astonishing and often of great utility, that result from the distribution of electrons in metals, semiconductors, and insulators. It also tells how the imperfections of real solids can be understood with simple models using the well-known experimental results and the theories. | |||||||||
| ECE5916 | Digital Integrated Circuits | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| It covers structures and operational principles of CMOS transistors and digital citcuits (INV, NAND, NOR, LATCH, Current Mirror), computation of sizing and delays, Flash A/D converter. | |||||||||
| ECE5917 | SOC Architectures | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| This course introduces basic components of system on chip and platform-based design for SoC. It covers the subjects on SoC system specification, platform-based design and platform architectures, embedded system hardware/ software components, programmable processor core in SoC, embedded memory architecture, and architectural integration of SoC | |||||||||
| ECE5918 | Computer Control of Electric Machines | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| This lesson theoretically considers servo motor and motion control technologies, on the base of mechatronics engineering. Computer is generally used as a controller and sensor signal processor because of fast computational capability and suitable architecture, this lesson experimentally deals with servo motor based on computer for understanding. | |||||||||
| ECE5919 | Power System Analysis | 3 | 6 | Major | Master/Doctor | 1-5 | - | No | |
| This lesson discusses the basic concepts of an electric power system. Main subjects are transmission line parameter, steady-state operation, system modeling, network modeling and numerical solution | |||||||||
| ECE5920 | Optimization Methods | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| Linear programming, nonlinear programming, iterative methods and dynamic programming are presented, especially as they relate to optimal control problems. Discrete and continuous optimal regulators are derived from dynamic programming approach which also leads to the Hamilton-Jacobi-Bellman Equation and the Minimum Principle. Minimum energy problems, linear tracking problems, output regulators and minimum time problems are considered. | |||||||||
| ECE5921 | Advanced Topics on Algorithm | 3 | 6 | Major | Master/Doctor | 1-5 | English | Yes | |
| The purpose of this course is to provide detailed understandings for time/space complexity, recurrences, algorithm design technique, lower bounds, graph/matrix/set algorithms, sorting, intractable problems. | |||||||||
| ECE5922 | Optical Phenomena and Applications | 3 | 6 | Major | Master/Doctor | 1-5 | Korean | Yes | |
| This lecture covers optical phenomena and their application. In particular, various optical fields, including modern optics, optical signal process, lasers, optoelectric devices, optical communication theory and their components will be presented. | |||||||||
| ECE5923 | Microelectronic Device Applications | 3 | 6 | Major | Master/Doctor | 1-5 | - | No | |
| The primary goal is to descibe the operting principles and VLSI technolgy of semiconductors devices including pn junctions, bipolar transistors, and MOSFETs. The second concerned topics are listed as deposition, diffusion, ion-inplamtation, metallization, etching and theirt related theory. A final goal is to learn basic theory of designing integrated-circuits and to design microelectronic devices for practice. | |||||||||
| ECE5928 | Seminconductor Device Characterization | 3 | 6 | Major | Master/Doctor | 1-5 | Korean | Yes | |
| The lecture is offered for the person who is reasonably familiar with the physics and operation of major semiconductor devices as in pn junction, bipolar transistors, MOS capacitors and transistors, solar cells, Schottky barrier diodes. By comparing most of the known characterization tools, a student get a firm grip on pros and cons of the various experimental methods. | |||||||||
| ECE5929 | Power Distribution Network Design in Electronic Circuit | 3 | 6 | Major | Master/Doctor | 1-5 | - | No | |
| As the circuit performance enhances with higher operating frequency and higher integration density, the importance of power delivery network in the electronic circuit has been greatly emphasized to implement low noise electronic circuit. This course deals with the analysis and design method of PDN (Power Delivery Network) of board/package level circuit. The power plane in board/package circuit is modeled, and the mechanism of SSN (Simultaneous Switching Noise) is investigated. Modeling of transmission lines with power planes, via, and de-caps (decoulping capacitors) is explored, and several PDN examples of high speed digital circuits are presented. Finally the effectiveness of EBG (Electromagnetic Band Gap) structure is analysed with some examples. | |||||||||
| ECE5930 | Signal Integrity Analysis and Design | 3 | 6 | Major | Master/Doctor | 1-5 | - | No | |
| Recently the importance of signal integrity (SI) in digital circuit has been greatly emphasized as the circuit performance enhances with higher operating frequency and higher integration density. This course deals with the analysis and design method of signal integrity of board/package/interconnect circuit. Basic concept of frequency dependent resistance, inductance, and capacitance of interconnects are investigated, and modeling method of single/multi-conductor transmission line is explored. Measurement methods of parasitic parameters are presented in both time and frequency domain, and the meaning of dissipation factor in lossy lines are explained. Cross talk in transmission lines are analysed and enhancement of signal integrity using differential signaling, termination, and appropriate signal return path is presented. | |||||||||