Undergraduate

  • Credit Requirement

    Credit Requirement
    Required/Elective Credit(minimum)
    Interdisciplinary Major Remark
    1st Track 2nd Track
    36 12
    Elective 18 6

    Fundamental Required Mathematics Course

    Fundamental Required Mathematics Course
    Course No. Required Mathematics Course
    MTH201 Differential Equations
    MTH203 Applied Linear Algebra

    Curriculum

    ※ Course opening semester is subject to be changed according to School’s situation.
    Core Required: 1TR/2TR Common
    Electrical Engineering Curriculum
    Course No. Course Title Cred.- Lect.-Exp Remarks Semester
    EE201 Basic Circuit Theory
    회로이론
    3-3-0 2
    EE231 Electromagnetics Ⅰ
    전자기학 Ⅰ
    3-3-0 1
    EE311 Signals and Systems
    신호및시스템
    3-3-0 1
    Total Credit 9
    Core Required: 1TR, Elective: 2TR
    Electrical Engineering Curriculum
    Course No. Course Title Cred.- Lect.-Exp Remarks Semester
    EE3011) Microelectronics Ⅰ
    전자회로 Ⅰ
    3-3-0 Prerequisite: EE201 1
    EE3201) Digital System Lab
    디지털시스템실험
    3-1-4 Prerequisite: EE201, CSE201 1
    Total Credit 6
    1) Microelectronics Ⅰ(EE301) and Digital System Lab(EE320) become elective courses to EE 2nd track students who follow the 2019 curriculum and beyond.
    Required1): 1TR / Elective: 2TR
    Electrical Engineering Curriculum
    Course No. Course Title Cred.- Lect.-Exp Remarks Semester
    EE211 Probability and Introduction to Random Processes
    확률과 랜덤프로세스개론
    3-3-0 2
    EE302 Microelectronics Ⅱ
    전자회로 Ⅱ
    3-3-0 Prerequisite: EE301 2
    EE312 Communications and Information Theory
    통신 및 정보 이론
    3-3-0 Prerequisite: EE211 1
    EE313 Automatic Control
    자동제어
    3-3-0 Prerequisite: EE311 2
    EE321 Electronics Experiment Laboratory
    전자회로실험
    3-1-4 Prerequisite: CSE201, EE201, EE301 2
    EE331 Semiconductor Engineering I
    반도체공학 I
    3-3-0 1
    EE411 Digital Signal Processing
    디지털신호처리
    3-3-0 Prerequisite: EE311 1
    Total Credit 21
    1)‘Required’ means: 1st track students can choose 6 courses out of the 7 required courses above.
    Elective
    Electrical Engineering Curriculum
    Track Course No. Course Title Cred.- Lect.-Exp Remarks Semester
    EE EE204 Electromagnetism Ⅱ
    전자기학 Ⅱ
    3-3-0 2
    EE233 Physical Electronics
    물리전자
    3-3-0 Prerequisite: PHY101, PHY103 2
    EE314 Computer Networks
    컴퓨터 네트워크
    3-3-0 Prerequisite: EE211
    Identical: CSE351
    2
    EE332 Semiconductor Engineering Ⅱ
    반도체공학 II
    3-3-0 Prerequisite: EE331 2
    EE341 Electric Energy Systems
    전기에너지공학
    3-3-0 2
    EE342 Microwave Engineering
    마이크로파공학
    3-3-0 Prerequisite: EE201, EE231 2
    EE344 Antenna Engineering
    안테나공학
    3-3-0 Prerequisite: EE204 2
    EE401 Analog Integrated Circuits
    아날로그집적회로설계
    3-3-0 Prerequisite: EE301, EE302 1
    EE402 Introduction to VLSI Design
    초고밀도 집적회로 설계
    3-3-0 Prerequisite: EE301 1
    EE404 Power Electronics
    전력전자공학
    3-3-0 Prerequisite: EE301, EE313 1
    EE412 Advanced Information Systems
    고급정보시스템
    3-3-0 Prerequisite: EE312 1
    EE414 Optimization Theory
    최적화 이론
    3-3-0 2
    EE431 Semiconductor VLSI Devices Engineering
    반도체집적소자공학
    3-3-0 2
    EE432 Optoelectronics
    광전자공학
    3-3-0 1
    EE480 Special Topics in EE Ⅰ
    전자및전기공학특론 Ⅰ
    3-3-0
    EE481 Special Topics in EE Ⅱ
    전자및전기공학특론 Ⅱ
    3-3-0
    EE482 Special Topics in EE Ⅲ
    전자및전기공학특론 Ⅲ
    3-3-0
    EE483 Special Topics in EE Ⅳ
    전자및전기공학특론 Ⅳ
    3-3-0
    EE484 Special Topics in EE Ⅴ
    전자및전기공학특론 Ⅴ
    3-3-0
    CSE CSE221 Data Structures
    데이터구조
    3-3-0 1,2
    CSE241 Object Oriented Programming
    객체 지향 프로그래밍
    3-3-0 1,2
    CSE3011) Object Oriented Programming
    컴퓨터구조
    3-3-0 Prerequisite: CSE201, CSE2511) 1
    CSE3112) Operating Systems
    운영체제
    3-3-0 Prerequisite: CSE251 2
    CSE463 Machine Learning
    기계학습
    3-3-0 Prerequisite: EE211, CSE331 2
    PHY PHY213 Modern Physics
    현대물리학
    3-3-0 Prerequisite: PHY101, PHY103 2
    PHY301 Quantum Physics Ⅰ
    양자물리학Ⅰ
    3-3-0 Prerequisite: PHY101, PHY103 1
    PHY427 Introduction to Plasma Physics
    플라즈마 물리학 입문
    3-3-0
    PHY315 Solid State Physics I
    고체물리학 I
    3-3-0 Prerequisite: PHY301 2
    Total Credit 84
    1) EE 1st track students can request prerequisite exemption of CSE251 for CSE301.
    2) EE 1st track students can request prerequisite exemption for CSE311.

    History of Courses Change in 2019-2020

    History of Courses Change in 2019-2020
    2019 2020
    EE312
    Introduction to Communications
    통신개론
    EE312
    Communications and Information Theory
    통신 및 정보 이론
    EE313
    Introduction to Control
    자동제어공학개론
    EE313
    Communications and Information Theory
    자동제어
    EE314
    Introduction to Networks
    네트워크개론
    EE314
    Computer Networks
    컴퓨터네트워크
    EE331
    IElectronic devices Ⅰ
    전자소자Ⅰ
    EE331
    Semiconductor Engineering I
    반도체공학 I
    EE332
    Electronic Devices Ⅱ
    전자소자Ⅱ
    EE332
    Semiconductor Engineering Ⅱ
    반도체공학 II
    EE341
    Introduction to Electrical Energy Systems
    전기에너지공학개론
    EE341
    Electric Energy Systems
    전기에너지공학
    EE412
    Communication Systems
    통신시스템
    EE412
    Advanced Information Systems
    고급정보시스템
    EE404
    Fundamentals of Power Electronics
    전력전자공학개론
    EE404
    Power Electronics
    전력전자공학
    EE414
    Introduction to Optimization
    최적화이론개론
    EE414
    Optimization Theory
    최적화이론

    Course Descriptions

    EE201 Basic Circuit Theory [회로이론]
    The aims of this course are to make the students understand the principles and the fundamental concepts of circuit analysis; to develop the student’s familiarity and understanding in modeling and analyzing circuits through a variety of real-world examples; and to extend the student’s ability to apply system analysis to other branches of engineering. Memory, circuits, communication and control system, design of VLSI, magnetically coupled networks, power analysis, laplace transform, capacitor, inductor, and polyphase circuits are main topics of the course. The PSpice tool will be introduced and used for basic experiments. This course is focused on both hands-on experience and design practice.
    EE211 Probability and Introduction to Random Processes [확률과 랜덤프로세스개론]
    This course introduces probability, random process, confidence interval, experimental design and hypothesis testing, statistical average, correlation, spectral analysis for wide sense stationary processes, random signals and noise in linear systems.
    EE231 Electromagnetics I [전자기학 I]
    This course is the first half of one-year electromagnetics course. It deals with basic electro- and magnetostatic phenomena and the related theories using vector calculus, such as coulomb and ampere law, electric and magnetic fields and their boundary conditions at the interface of different media. It also covers the fundamental aspects of dielectric and magnetic materials, and electromagnetic induction.
    EE233 Physical Electronics [물리전자]
    This course covers fundamentals of quantum mechanics and solid-state physics, which are essential for studying semiconductor devices such as photonic devices, electronic devices and integrate circuits. Various interesting device examples in real applications will be discussed together. This course will be a preparation for courses Electronic Devices I, Optoelectronics, and Nanophotoncis.
    EE301 Microelectronics I [전자회로 I ]
    This course covers an introduction to electronic circuits and the analysis and design of transistor amplifiers. First, the course extensively explains the basic operation principles of diodes, BJTs, and MOSFETs derived from physical structures and gives a concept of equivalent device models. Then, we will study the design and analysis of basic BJT and FET amplifiers and differential and multi-stage amplifiers.
    EE302 Microelectronics II [전자회로 II ]
    This course is the succession of the MicroelectronicsⅠ course where the material covered focused on single elements and their operational principles. In Microelectronics Ⅱ, amplifiers, current mirrors, frequency response, and stability will be covered to understand the implementation of microelectronics.
    EE311 Signals and Systems [신호및시스템]
    This course introduces time-domain frequency domain response using Fourier series, Fourier transform, Laplace transform, discrete Fourier series and transform, sampling, z-transform, relationship between time and frequency descriptions of discrete and continuous signal and linear time invariant systems.
    EE312 Communications and Information Theory [통신 및 정보 이론]
    This course introduces core concepts in analog and digital communication systems. The topics include Fourier transform, communication signals, amplitude modulation (AM), phase and frequency modulation (PM and FM), noise in communications, techniques in analog to digital transformation (sampling and quantization), and an introduction to source and channel coding.
    EE313 Automatic Control [자동제어]
    This course introduces fundamentals of linear systems control: mathematical modeling, analysis, and design of systems, transfer function, root locus, bode diagram, nyquist method, and state space method.
    EE314 Computer Networks [컴퓨터 네트워크]
    This course provides the fundamental concepts of computer networking and exercises for network programming. The topics covered in this course are data link, networking, transport, and application layers.
    EE320 Digital System Lab [디지털 시스템 실험]
    This experiment course related to basic circuit theory and digital systems is focused on both hands-on experience and design practice with the following experiments: 1. Utilization of experimental equipments such as oscilloscope, power supply, and function generator, 2. Basic electric circuit theory with R, L, and C circuit networks, 3. Various digital circuit and systems, 4. Design specific digital system for given functionality as a term project.
    EE321 Electronics Experiment Laboratory [전자회로실험]
    Experiments related to circuit theory and electronic circuits are performed. This course is focused on both hands-on experience and design practice with the following experiments: Circuit theory: 1. Measuring equipments and RC transient response, 2. Phasor and AC steady-state response, 3. 3-phase circuits. Electronic circuit: 4. Diode and BJT characteristics, 5. BJT and MOSFET amplifier, 6. Application of operational amplifiers. Design: 7. Sine/square wave function generator design, 8. Active filter design, 9. DC power supply design.
    EE331 Semiconductor Engineering I [반도체공학 I]
    This course covers fundamental physical concepts related to electronic devices, i.e., crystal structure of semiconductor materials, electronic energy band, dopants, carrier transport. Then it introduces the basic working principles of PN junction and Metal-Oxide-Semiconductor (MOS).
    EE332 Semiconductor Engineering Ⅱ [반도체공학 Ⅱ]
    This course covers operation principles of various electronic devices such as Metal-Oxide-Semiconductor Field Effect Transistor (MOSFET), Bipolar Junction Transistor (BJT), Junction FET (JFET) and High Electron Mobility FET (HEMT). Microwave, photonic and power devices will be discussed as well.
    EE341 Electric Energy Systems [전기에너지공학]
    This course introduces elements of modern electrical energy systems, including energy resources, energy conversion, power delivery and processing. The course also covers the basic principles on power converters and electromechanical energy conversion.
    EE342 Microwave Engineering [마이크로파공학]
    This course is intended to introduce the general background that is required for RF, microwave, mm-wave, and THz designs. After a brief review of EM and transmission line theory, microwave network and impedance matching concepts are introduced. With the understanding of microwave network, the design of microwave components including power divider, couplers, resonators, active RF circuits, and RF systems will be covered.
    EE344 Antenna Engineering [안테나공학]
    This course introduces the fundamental principles of antenna engineering in wireless communications. Various types of antennas and their applications will be covered with focus on linear wire antennas, loop antennas, aperture antennas, and microstrip antennas. Modern array antenna technologies such as smart antennas, Radar, direction finding, and interference mitigation will also be explored.
    EE401 Analog Integrated Circuits [아날로그집적회로설계]
    This course covers basic concepts of fabrication, operation and design techniques related to CMOS integrated circuits. It also covers analysis and design of analog ICs using analytic techniques and CAD tools. Topics include amplifiers, current sources, output circuits, and other analog blocks.
    EE402 Introduction to VLSI Design [초고밀도 집적회로 설계]
    This course studies analysis and design techniques for implementations of very large-scale integrated (VLSI) circuits, MOS technology, logic, interconnect, and memory by using electronic design aid (EDA) tools. Topics include full custom design methodology of logic gate generations, timing/power simulations, layout, DRC/LVS rule checking, and floor plan. Projects will be conducted to develop and lay out circuits.
    EE404 Power Electronics [전력전자공학]
    The objective of this course is to introduce essential elements for controling and interfacing electric power. Main topics include power rectifiers for AC-DC conversion, PFC circuits, various DC-DC converters, resonant converters, bidirectional converters, and inverters for DC-AC conversion. This course is focusing on static power conversions; however, an introduction to electromechanical energy conversion and the control and drives of electric machines will be served.
    EE411 Digital Signal Processing [디지털신호처리]
    This course introduces sampling of continuous-time signals and reconstruction of continuous signals from samples, spectral analysis of signals, fast Fourier transform, design of finite and infinite impulse response filters, signal flow graphs and filter implementation methods.
    EE412 Advanced Information Systems [고급정보시스템]
    This course covers fundamental techniques for digital communication systems. The topics include analog to digital transformation using sampling and quantization, baseband and bandpass digital transmission, and an introduction to source and channel coding.
    EE414 Optimization Theory [최적화 이론]
    This course introduces the fundamentals of theories and applications for optimization. This course covers optimization theory, optimization algorithms, and optimization applications such as control, machine learning, communication and image and signal processing.
    EE431 Semiconductor VLSI Devices Engineering [반도체집적소자공학]
    In this course, we study in depth how the various semiconductor devices operate by using analytical approach and computer simulation. The fabrication processes and the operating principles of the manufacturing equipments are also covered. Finally, the application of semiconductor devices to actual integrated circuits and new types of devices will be discussed.
    EE432 Optoelectronics [광전자공학]
    This introductory course is intended to familiarize students with underlying principles of optoelectronic and optical communication devices. Topics of this course include an overview of laser, fiber optic communication systems, optics review, light wave fundamentals, light detectors, noise analysis, and system design.
    EE480 Special Topics in EE Ⅰ [전자및전기공학특론 Ⅰ]
    This course introduces new research topics in the field of Electrical Engineering I.
    EE481 Special Topics in EE Ⅱ [전자및전기공학특론 Ⅱ]
    This course introduces new research topics in the field of Electrical Engineering II.
    EE482 Special Topics in EE Ⅲ [전자및전기공학특론 Ⅲ]
    This course introduces new research topics in the field of Electrical Engineering III.
    EE483 Special Topics in EE Ⅳ [전자및전기공학특론 Ⅳ]
    This course introduces new research topics in the field of Electrical Engineering Ⅳ.
    EE484 Special Topics in EE Ⅴ [전자및전기공학특론 Ⅴ]
    This course introduces new research topics in the field of Electrical Engineering Ⅴ.