For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| ECE4273 | Introduction to Mobile Communications | 3 | 6 | Major | Bachelor/Master | Electrical and Computer Engineering | - | No | |
| This course covers various topics on mobile communications, which include cellular systems, cognitive radio networks, heterogenous wireless networks, multiple access techniques (CDMA/OFDMA/FDMA/TDMA), wireless protocol, transmission techniques in wireless channels, synchronization techniques, design and management of mobile communication networks, frequency management and next generation mobile communication systems. | |||||||||
| ECE4275 | Solid State Physics for Electrical Engineers | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | English | Yes |
| The fundamentals of solid-state physics is to be lectured, in order to design and develop the solid-state electron devices. To figure out the basic properties of insulator/semiconductor/conductor as well as how to draw the energy band diagram, the fundamentals on solid-state physics are provided. Afterwards, students can learn how carriers are moving in semiconductor (e.g., drift, diffusion, recombination-generation). Before taking the advanced classes such as semiconductor device engineering and nano device engineering, the theory for metal-semiconductor junction and p-n junction are to be studied in great detail (including DC, AC, and transient responses). | |||||||||
| ECE4276 | Introduction to Intelligent Bioelectronic Devices | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | - | No |
| The course covers the basic knowledge to understand interdisciplinary research area of modern flexible and stretchable devices in the field of bioelectronics. The convergence of electrical, material, and nano-scale fabricating techniques allows recent novel bioelectric platform, with a consequences in improved performance and multimodal operation. In this course work, we will discuss the electrode geometry, device structures, signal analysis, and other topics related to the implantable and biointegrated electronics. All materials in the course work requires the basic knowledge covered in other electrical engineering course from the Freshman to Junior. | |||||||||
| ECE4277 | RF System Engineering | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | - | No |
| Modern electronic systems demand smaller, faster, and more efficient analog and digital circuits. This course introduces the fundamental concepts and analysis techniques of RF engineering to tackle the high-speed problems in designing analog and digital circuit and systems. The lecture begins with a review of the basics - the origin of resistance, capacitance, and inductance - then progresses to more advanced topics such as transmission line theory including single and multiconductor systems with eigen mode analysis, resonant circuits, impedance termination and matching, network analysis and functions and operation principles of high frequency active circuit building blocks. In addition, the course describes system level design issues with link budget analysis examples and applications in RF systems. This course will be valuable to senior undergraduate and graduate students interested in for high-speed analog and digital design. | |||||||||
| ECE4278 | SOC Design and Practice | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| This course delivers fundamentals of SoC design, including basic concepts, components, and design flows. It provides an introduction to SoC and its components. It also teaches design flows of SoC, including Register-Transfer-Level (RTL) design, verification, logic synthesis, formal verification, clocking, synchronous/asynchrouns signal interface. | |||||||||
| ECE4279 | Memory Semiconductor Design | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | English | Yes |
| CMOS memory devices are known as traditional digital devices. In order to suffice tough requirements for advanced IC’s and artificial intelligence applications, new memory devices beyond conventional DRAM/SRAM/flash are suggested. This course starts from brief review of memory system, and expands to operating principles of memory devices, design practice, and performance metrics. New memories such as emerging non-volatile memories, content addressable memory, and process-in-memory are covered at the end of course. Practice on memory circuit design and evaluation is included as a part of homework assignment. | |||||||||
| ECE4280 | Wireless Networks Cornerstone | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | English | Yes |
| This course provides an overview on wireless networking principles and technologies from the view point of computer science majors. The major themes will focus on the fundamentals and principles covering the protocol stacks of wireless networks, and wireless data services. | |||||||||
| ECE4281 | Flexible Electronic Materials | 3 | 6 | Major | Bachelor/Master | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| The course covers the basic concepts for understanding the electrical and mechanical characteristics of flexible functional electronic materials. Based the basic knowledge, we will learn fundamental technologies such as transfer-printing and printing processes for fabricating the flexible electronic devices. Based on the basic knowledge originating from Electric Circuits, Logic Circuits, and Solid State Electronic Devices, we will understand how RLC filters/amplifiers, transistors, logic gates, resistive random access memory devices stably operate under tensile/compressive strains. The aim of this class is to provide opportunities for learning the application to flexible display modules, sensors, and wireless integrated circuits. | |||||||||
| ECE7001 | Semiconductor Device Simulation and Practice | 3 | 6 | Major | Bachelor/Master/Doctor | Electrical and Computer Engineering | Korean | Yes | |
| The primary goal is to describe the operating principles and device fabrication technology in electrical and electronic engineering. Lecture deals with an advanced method of material property characterization and device design (SILVACO simulation). Atlas with Spices 2B, 2D Device Simulation. Blaze, 2D Hetero junction Bipolar transistor, and III-V compound Simulator, Laser, 2D Semiconductor Laser Simulator, Giga, 2D Lattice Heating Simulator with Heat Sink, Mixed Mode, 2D Mixed Circuit and Device Simulator, TFT, 2D Amorphous and Poly Silicon Simulator, Luminous, 2D Optoelectronic Simulator, Quantum, 2D Quantum Effects Simulator, Ferro, 2D Ferroelectric Material Simulator. | |||||||||
| 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. | |||||||||
| EEE3006 | Modern Optics | 3 | 3 | Major | Bachelor | 3-4 | Electronic and Electrical Engineering | Korean | Yes |
| The goal of this class is to understand the propagation of light in free space and in materials. The light propagation is first explained by the wave theory or Huygens's principle. Then the principles of reflection and refraction are explained. Next the light propagation is explained by the oscillating dipoles of atoms. Based on this theory the light scattering is explained. Next the operation of simple optical systems such as simple lens system, compound lens system, camera and human eyes is explained. | |||||||||
| EEE3009 | Display Electronics | 3 | 3 | Major | Bachelor | 3-4 | Electronic and Electrical Engineering | Korean | Yes |
| This course studies various display systems including TFT-LCDs. Newly emerging devices like electroluminescence (EL), field emission display (FED), and plasma display panel (PDP) are the major topics in the course work. Important consideration factors in display system are given as fast response time and excellent mechanical properties of EL, high speed operation and long device lifetime of FED, and ease of large area implementation of PDP. | |||||||||
| EEE3011 | Digital Signal Processing | 3 | 3 | Major | Bachelor | 3-4 | Electronic and Electrical Engineering | English | Yes |
| The topics to be covered are : Analysis and process techniques used in computer processing of signals. Analog to digital conversion. Recursive digital filters, and matched filters. Time series analysis of waveforms, z-transforms, and Fast Fourier transforms (FFT) for digital signal analysis, complex demodulaion and data compression. Cepstrum tecnique and spectral estimation. | |||||||||
| EEE3012 | Digital Communication | 3 | 3 | Major | Bachelor | 3-4 | Electronic and Electrical Engineering | Korean | Yes |
| This course covers the essential theories and principles of digital and data communication. The topics to be included are ; digital network configuration, circuit and packet switching system, digital representation of information, synchronous and asynchronouse time division multiplexing, network architecture modem, layered protocol, packet data network, local area network, and the concept of ISDN (Integrated Services Digital Network). | |||||||||
| EEE3023 | Electromagnetic Wave Engineering | 3 | 3 | Major | Bachelor | 3-4 | Electronic and Electrical Engineering | Korean | Yes |
| This course covers theory of electromagnetic wave and the application. This course assumes the student has basic understanding of electromagnetic theory and emphasizes on the practical application of wave trammission and propagation.Topics to be covered include: transmission lines, graphical aids to transmission line analysis(Smith chart), transmission line impedance matching, transmission line equations and representation, field equations, propagation of plane waves and guided waves, resonant cavities, waveguide as a circuit element,radiation of elecromagnetic waves, and general theory on antennas. | |||||||||