For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| EAM2062 | Electroceramic Materials | 3 | 6 | Major | Bachelor | 2-3 | Advanced Materials Science and Engineering | Korean | Yes |
| This subject covers crystalline structure of conventional and newly investigated electroceramic materials, point defects (doponts), physical properties (semiconducting and transport phenomena) of electroceramic materials. This subject is intended to provide basic knowledge in the field of electroceramic materials. | |||||||||
| EAM3003 | Phase Transformation | 3 | 6 | Major | Bachelor | 3-4 | Advanced Materials Science and Engineering | Korean,English | Yes |
| Thermodynamics and kinetics of phase transformations, phase transformation mechanisms, phase change in metals and alloys, massive and order-disorder transformations, martensitic transformation, and precipitation hardening. | |||||||||
| EAM4017 | Metals | 3 | 6 | Major | Bachelor/Master | Advanced Materials Science and Engineering | Korean | Yes | |
| This field studies the properties of metals and alloys as affected by manufacturing, mechanical deformation and heat treatment which is concerned with the physical, mechanical and chemical characteristics of metals and alloys. This course includes phase transformation, welding metallurgy, fracture mechanics, and corrosion for alloy design. | |||||||||
| EAM4020 | Introduction to organic and polymeric materials | 3 | 6 | Major | Bachelor/Master | Advanced Materials Science and Engineering | English | Yes | |
| This course introduces structures, properties, synthesis, and applications of various organic and polymeric materials. | |||||||||
| ECE4238 | Linear Systems | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | - | No |
| Methods of analysis for continuous and discrete-time linear systems. Convolution, classical solution of dynamic equations, transforms and matrices are reviewed. Emphasis is on the concept of state space. Linear spaces, concept of state, modes, controllability, observability, state transition matrix, state variable feedback, compensation, decoupling are treated. | |||||||||
| ECE4247 | Power Electronics System Analysis | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | - | No |
| Inverters and converters play an important role to operate fuel cell systems, hybrid electric vehicles, and etc. In this subject, design and control of various power conversion circuits according to the application conditions. Completing this subject, one can handle hardwares and softwares for power conversion circuits and can utilize the theory and technique for industry applications | |||||||||
| ECH2005 | Chemical Engineering ThermodynamicsⅠ | 3 | 6 | Major | Bachelor | 2-3 | Chemical Engineering | Korean,English | Yes |
| The primary objective of this course is to teach the basic principle and laws of the thermodynamics. This course covers applications of thermodynamic law in chemical engineering such as thermo-characteristics of fluids, expansion, compression and refrigeration, thermodynamic analysis and basic design of chemical plant. | |||||||||
| ECH2011 | Instrumental Analysis for Chemical Engineering | 3 | 6 | Major | Bachelor | 2-3 | Chemical Engineering | English | Yes |
| Fundamental principles and characteristics in instrumental analysis will be lectured in this course. The qualitative and quantitative analytical techniques in measurement of temperatures and flow rate, chromatography, and UV/VIS and FTIR spectroscopy, and mass Spectroscopy, etc. for evaluating the organic or inorganic materials will be introduced. | |||||||||
| ECH3053 | Chemical Reaction Engineering | 3 | 6 | Major | Bachelor | 3 | Chemical Engineering | Korean,English | Yes |
| The course of "Engineering of Chemical Reactions" is focused on developing fundamental reaction kinetics according to the types of ideal reactors such as CSTR and PFTR, which is essential for designing chemical processes. This course will also cover the characteristics of representative ideal reactors, analysis of application of reactors and effects of temperature and pressure to kinetic parameters and reaction rates and so on. In addition, the methods for optimization and design of reactors of single/multiple reactions and isothermal/adiabatic reaction will be also included in this lecture to enhance the student's abilities as a chemical engineer. | |||||||||
| ECH3060 | Electronic Materials for Chemical Engineers | 3 | 6 | Major | Bachelor | 3-4 | Chemical Engineering | Korean,English | Yes |
| This lecture will provide general view on the current status, general material properties, and future perspective of organic functional materials used in industries, specially in electronics and information industries. This lecture will provide the reason why a specific organic materials should be use to the particular electroins or information industries by discussing the subject on the structure-property-processing relationships viewpoint. | |||||||||
| ECH3067 | Process Control & Design | 3 | 6 | Major | Bachelor | 3-4 | Chemical Engineering | Korean,English | Yes |
| This course presents introductory concepts of process dynamics and control, dynamic modeling, transfer function models, system identification, feedback control concepts and design methods, their application to controller design, and advanced control strategies including feed-forward, and cascade designs. MATLAB/SIMULINK will be introduced and used to simulate and examine the process dynamics and effectiveness of various control strategies. This module is targeted at chemical engineering students who already have a basic knowledge of chemical engineering processes. After successful completion of the course, students will be able to: (1) Simplify a first-principles dynamic model by linearization and convert it to a transfer function model convenient for analysis and controller design (2) Classify the dynamic behavior of complex processes based on their time domain and transfer function representations and obtain empirical models using step response and regression methods (3) Analyze stability and performance of feedback control systems (4) Design PID controllers using conventional tuning rules (5) Implement enhanced control strategies including, feedforward control, and cascade control, to achieve improved performance compared to the conventional feedback system (6) Use computer-based tools (MATLAB) to simulate process dynamic and feedback control systems | |||||||||
| ECH4017 | Plasma Processing for Semiconductor Manufacturing | 3 | 6 | Major | Bachelor/Master | Chemical Engineering | - | No | |
| This lecture discusses plasma technology that is a key technology in semiconductor processing. - Plasma physical and electrical characteristics of plasmas - Chemical characteristics of plasmas - Plasma etching and deposition processes - Plasma diagnostics and monitoring technology | |||||||||
| EEE2007 | Semiconductor Electronics | 3 | 3 | Major | Bachelor | 2-3 | Electronic and Electrical Engineering | Korean | Yes |
| A background information of Physics in Electronics will give plenty of benefits to the student taking this course. Junction analysis is expanded from homojunc-tion to heterojunction. Semiconductor growth technology, diffusion mechanism, donor and acceptor materials, metalization method and surface state effect of semiconductor are described mainly featuring silicon and compound semiconductorsThe main stream line of the lecture will be the different semiconductor device applications such as bipolar transistors, field effect transistors, integrated circuits and optoelectronic devices like light emitting diode, photovoltaic devices, laser, detectors. device application includes device fabrication, analysis, design and characterization of the different semiconductor devices. | |||||||||
| EEE2012 | Circuit Theory II | 3 | 3 | Major | Bachelor | 2-3 | Electronic and Electrical Engineering | Korean,English | Yes |
| Nonsinusoidal wave, transient phenomena, laplace transform. Fourier analysis techniques. Admittance parameters, Impedance parameters, Hybrid Admittance parameters. Parameter Conversions. T-π equivalent networks. Two-port networks Sinusoidal frequency analysis, Resonant circiutis. Distributed parameter circuit. | |||||||||
| EEE2014 | Electronic Circuits II | 3 | 6 | Major | Bachelor | 2-3 | Electronic and Electrical Engineering | Korean,English | Yes |
| Introduction to advanced concepts of active electronic circuits. Topics include operational amplifier characteristics and systems, stability and oscillators, wave shaping and waveform generator, analog-to-digital converter, digital-to- analog converter, active filters, and power circuits and systems. | |||||||||