For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| ECE4286 | Artificial intelligence semiconductor memory device | 3 | 6 | Major | Bachelor/Master | Electrical and Computer Engineering | - | No | |
| Artificial intelligence algorithms based on deep neural networks (DNN: Deep Neural Networks) are demonstrating performance that is similar to or exceeds that of humans in many complex cognitive tasks. However, the energy efficiency of current Neumann computing systems implementing deep neural network algorithms is very low compared to the human brain. To solve this problem, neuromorphic hardware, which consists of densely connected parallel neurons and synapses that mimics the brain neural network structure, was proposed. The objective of this lecture is to deliver a driving principles of neuromorphic hardware and memristor memories, which expresses the weight of synapses in neuromorphic hardware. It will be introduced the operating principles of various memristors, including floating gate memory type, resistive memory type, phase change memory type, magnetic random access memory type, and ferroelectric memory type. | |||||||||
| 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. | |||||||||
| EEE2001 | Basic Circuits Laboratory | 2 | 4 | Major | Bachelor | 2-3 | Korean,Korean | Yes | |
| This course consists of 3 main subjects. The first one is to practice skills in handling basic electrical and electronic equipments, the second takes the tests of basic electric circuit theory, and the last one are tests of linear electrical device characteristics. Basic equipment such as an ammeter, volt-meter, tester, oscilloscope, function generator and power supplier are included. Basic electric circuit theory covers Kirchhoff's voltage, current law, Superposition law, Thevnin-Norton's law, and resonant characteristics of R-L-C circuits. This lecture will provide a student to understand basic properties of linear elemental devices like resistor, inductor, capacitor, and their combinations in electrical circuits. | |||||||||
| EEE2004 | Electronic Circuits Laboratory | 2 | 4 | Major | Bachelor | 2-3 | Korean,Korean | Yes | |
| This course is to develop the ability to match the results of schematic design of electronic circuits to their experimental results. The course begins with measurement methods of basic instruments, their interface to the computer, fabrication methods of PCB and brief introduction to SPICE. Next, the basic building blocks for complicated circuit design are experimented. The experimental contents include rectifier, operational amplifier, single transistor amplifier, output stage amplifier, multistage amplifier, differential amplifier, active filter, waveform generator, and AD-DA converter. Finally, term project will be assigned to every laboratory groups to implement the complex circuit on the real PCB. | |||||||||
| EEE2006 | Physical Electronics | 3 | 3 | Major | Bachelor | 2-3 | English,Korean | Yes | |
| Reviewing macroscopic and microscopic properties, the lecture introduces a basictheory of quantum mechanics. Fundamental properties of solid state such as the crystal structure, bonding mechanism, thermodynamic and electrical properties are studied. Many body effects are treated to study physical theories of real solid state. The study of basic electronic structures in carried out to under- stand the fundamental physical theories of semiconductor. The concepts of charge carriers in semiconductor and conductivity properties are covered to deal with operational theories of the pn junction, pn junction diode. The object of this lecture is to gain theoretical background of semiconductor in terms of physics and to expand the achieved theory to the practical applica- tions such as semiconductor diode, transistor, field effect transistor, integrated circuits and semiconductor lasers. | |||||||||
| EEE2007 | Semiconductor Electronics | 3 | 3 | Major | Bachelor | 2-3 | 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. | |||||||||
| EEE2008 | Signals and Systems | 3 | 3 | Major | Bachelor | 2-3 | Korean,English,Korean | Yes | |
| Fundamentals of the analysis and processing of continuous and discrete signals in both time and frequency domains. Linear Time Invariant (LTI) systems and filtering. convolution, Fourier Series(FS), Fourier Transform(FT), Transform(DFT), Introduction to analog and digital communications and the Sampling Theorem Computer based simulation and data processing are used to demonstraste the above concepts in a laboratory settings. | |||||||||
| EEE2009 | Electromagnetism I | 3 | 3 | Major | Bachelor | 2-3 | Korean,English,Korean | Yes | |
| General grasp of electrostatics and magnetostatics. Introductions to electric field intensity, electric flux density, electric potentials, Gauss's law, and Divergence theorem. Material characteristics of conductors and dielectrics are explained, which produce the concept of capacitance. Analytic and numerical solutions of electric field, using Laplace's and Poisson's equation. Finally, Bio-Savart law, Ampere's law, and Stoke's theorem are introduced for magnetostatics. | |||||||||
| EEE2010 | Electromagnetism Ⅱ | 3 | 3 | Major | Bachelor | 2-3 | Korean,English,Korean | 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. | |||||||||
| EEE2011 | Circuit Theory I | 3 | 3 | Major | Bachelor | 2-3 | Korean,English,Korean | Yes | |
| Circuit element, Kirchhoff's law, Ohm's laws. Sine wave altenating current, Instantaneous value, average value, effective value. R-L-C series circuit and parallel circuit. Phasor representation of sine wave AC, impedance and admittance circuit. Two port network, bridge circuit, coupled circuit. Active power, complex power. Constant voltage and current source. Thevenin's and norton's theorem. Polyphase AC curcuit, balanced and unbalanced 3-phase curcuit, method of symmetrical coordinates. | |||||||||
| EEE2012 | Circuit Theory II | 3 | 3 | Major | Bachelor | 2-3 | Korean,English,Korean | 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. | |||||||||
| EEE2013 | Electronic Circuits I | 3 | 3 | Major | Bachelor | 2-3 | Korean,English,Korean | Yes | |
| Topics include physical models of diodes and transistors, FET circuits, small- and large-signal operation, advanced treatment of active circuits, low frequency amplifiers, frequency response of amplifiers, and feedback amplifiers characteristics. | |||||||||
| EEE2014 | Electronic Circuits II | 3 | 6 | Major | Bachelor | 2-3 | English,Korean | 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. | |||||||||
| EEE2017 | Electronic and Electrical Programming Laboratory | 2 | 4 | Major | Bachelor | 2-3 | Korean,English,Korean | Yes | |
| The course offers practical C programming Experiences to the students who have basic knowledge of C language. The programs in this laboratory will be basic data structures, and circuit modeling. | |||||||||
| EEE3006 | Modern Optics | 3 | 3 | Major | Bachelor | 3-4 | 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. | |||||||||