For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| CES2004 | Semiconductor manufacturing process and materials | 3 | 6 | Major | Bachelor | 2-3 | Advanced Semiconductor Convergence Track | - | No |
| This course covers the principles and applications of various unit processes used for the fabrication of semiconductor devices: materials, lithography & etching, oxidation, diffusion, ion implantation, and thin film deposition. Lastly, based on the in-depth understanding of unit processes, integration processes such as metallization will also be studied. Through this, students will learn in detail about the eight major processes and materials related to semiconductor manufacturing, allowing students to quickly acquire basic knowledge related to semiconductor manufacturing. | |||||||||
| CES2007 | Basics of semiconductor materials analysis | 3 | 6 | Major | Bachelor | 2-3 | Advanced Semiconductor Convergence Track | - | No |
| This course is designed to help undergraduate students understand and follow various experimental techniques that are useful in the field of basic semiconductor materials analysis. Therefore, this course consists of an introduction to the operating principles and practical characteristics of microscopy and spectroscopy techniques that are widely used in research and industrial fields. This course will be operated in a kind of semi-flipped learning manner, where pre-recorded lecture videos will be provided and real-time lectures will be conducted with reviews, questions and answers, and discussion classes. | |||||||||
| CES3001 | Semiconductor process material properties | 3 | 6 | Major | Bachelor | 2-3 | Advanced Semiconductor Convergence Track | - | No |
| In this lecture, we learn about electronic materials and their bonding, which are the basis for understanding and application of electronic device driving principles, and study the synthesis, characteristics, and application cases of various nanoelectronic materials. In the first half of the lecture, we study electronic materials and bonding theory based on quantum mechanics and solid-state chemistry, and in the second half of the lecture, we introduce the synthesis and application of various nanoelectronic materials such as organic, inorganic, and organic-inorganic composite materials. In particular, we study examples of electronic materials that have recently been attracting attention in the industrial world and how what we studied theoretically can be applied to the actual implementation of electronic devices. | |||||||||
| CES3006 | System and memory semiconductor design | 3 | 6 | Major | Bachelor | 3-4 | Advanced Semiconductor Convergence Track | - | No |
| First ever lecture on each covering introduction of memory systems that is the first part of the computer architecture and all kinds of semiconductor memory products. I am going to give you a strong base to work as a semiconductor memory developer as well as computer architect or memory architect. Through this course, you will learn in detail about system and memory design to acquire professional knowledge in the field of semiconductor memory and system-related design. | |||||||||
| CHS2012 | IoT Project | 2 | 4 | Major | Bachelor | 1-4 | Challenge Semester | - | No |
| It is a course for students who are not familiar with software and hardware, but who are interested in Internet of Things area. It aims to provide easy and convenient steps of the area, including education of C language basics and various digital/analog sensor control conducted with a toolkit such as Arduino. Communication skills and cooperative spirit can be obtained by carrying out IoT projects through group activities. | |||||||||
| DED4001 | Artificial Intelligence for Display Engineering | 3 | 6 | Major | Bachelor/Master | 1-4 | Display Engineering | Korean | Yes |
| ‘Artificial Intelligence for Display Engineering’ is a course that introduces advanced artificial intelligence (AI) techniques for display engineering. It covers both conventional display manufacturing and inspection, including OLED and MicroLED panels, and emerging display technologies such as AR, VR, and XR systems, holographic displays, and light-field displays. The course presents key AI concepts used in display image processing, 3D scene understanding, and optical modeling, ranging from convolutional neural networks and vision transformers to Implicit Neural Representation (INR) methods such as Neural Radiance Fields (NeRF). Students learn the basic principles of NeRF, 3D Gaussian Splatting (3DGS), and inverse rendering, which are essential for geometric reconstruction, high-quality rendering, and distortion correction in immersive display environments. In addition, the course introduces AI techniques used in real manufacturing and inspection workflows, including defect image analysis, anomaly detection, defect correction, super-resolution, and data-driven optical property prediction. Through practical analysis of real inspection data, students gain experience applying AI to both traditional and next-generation display systems. The course aims to cultivate interdisciplinary talent capable of contributing to intelligent display manufacturing, next-generation display design, and AI-based rendering and optical correction. | |||||||||
| DED7002 | OLED1 | 3 | 6 | Major | Bachelor/Master/Doctor | Display Engineering | Korean | Yes | |
| This advanced OLED course for graduate students majoring in display technology is divided into two sections: OLED1 and OLED2. OLED1 covers the fundamental theories of OLED engineering, while OLED2 covers OLED device manufacturing technology and applications. Students taking this course are strongly encouraged to take "Display Engineering" as a prerequisite. The main content of OLED1 is as follows. The introductory course provides an overview of the current state of the display industry, the limitations of OLED technology, its core technology, and future prospects. Lectures on the fundamental theories of OLED technology, including organic semiconductor physics and the structure and operating principles of OLED devices, will provide a comprehensive and fundamental understanding of the technology. Next, lectures will be given on the electro-optical properties and analysis methods of OLED devices, as well as the theory and properties of organic materials applied to device fabrication. The OLED1 course aims to enable graduate display majors to further develop their research capabilities through a specialized understanding of OLED operating theory, device structure and operating principles, and organic materials. In addition, this lecture will help you understand the current state of the display industry and the limitations of OLED technology, and suggest directions for research on next-generation display technology. | |||||||||
| ECE4223 | Semiconductor Process Technology | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | English | Yes |
| This course helps to understand the overall semiconductor processes by introducing the theory and the application of unit processes; photolithography, photo-mask, dry-etch, cleaning, chemical-mechanical polishing(CMP), diffusion and thin film, and module processes; transistor, isolation, capacitor, interconnection. This also suggests the direction of process technologies for the future generations. | |||||||||
| ECE4233 | Simulation Engineering of Electric Power Systems | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| The objective of this lecture is to present methods of power system simulation, particularly with the aid of a personal computer, in sufficient depth to give the student the basic technique at the graduate level. Main subjects are steady-state & transient power system simulation, fault modeling technique, FACT(flexible alternating current transmission) simulation and the usage of EMTP, ATP, PSCAD/EMTDC. | |||||||||
| ECE4237 | Robotics | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| This course discusses the kinematics and the dynamics of manipulators. The path planning of each joint and some control algorithms of manipulators are also discussed. | |||||||||
| ECE4238 | Linear Systems | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | English | Yes |
| 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. | |||||||||
| ECE4245 | Automation and Design of Electric Power System | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| In many coutries, the electric supply industry is undergoing a significant restructuring that has only just begun. Fully competitive markets of electric energy are fairly recent phenomena, and the existing competitive markets have not experienced significant of resource shortages yet. This course deals with the basic principles of power system automation from the point view of the central control facilities under competitive environment. And it discusses central computers used to process power system economic operating data, present vital data to an operator, and allow the operator to implement commands to equipment field. Also it contains the economic load dispatch, the Gauss-Seidel, Newton-Raphson, and decoupled method to iteratively calculate network power flow. | |||||||||
| ECE4246 | Digital Control | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | - | No |
| Many industrial control systems include digital computers as an integral part of their operation. Recent trends toward digital control of dynamic systems, rather than analog control, is mainly due to the recent revolutionary advances in digital computers and to advantages found in working with digital signals rather than continuous-time signals. Also, the availability of low-cost microprocessors and microcomputers established a new trend for even small-scale control systems to include digital computers to obtain optimal performance. The main purpose of this course is to present a comprehensive treatment of the analysis and design of discrete-time control systems. In particular, this course provides clear and easy-to-understand explanations for concepts involved in the study of discre-time control systems. | |||||||||
| 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 | |||||||||
| ECE4249 | Computer Vision | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| This course focuses in the study of theories for image analysis. The first part consists of Image formulation model, early processing, boundary detection, region growing and segmentation, motion detection, merging and introduction of morphology. The second part, we cover basic concepts of statistical model, dis- criminant function, decision boundary and rules and neural network for visual pattern recognition. | |||||||||