This course covers the basic principles of circuit theory, and pursues easy understanding by executing practical exercises. The main areas of study include direct/alternating current experiments using elements such as resistance, capacity, inductor etc, movement principles of basic measuring instruments, and composition of rectifier circuits using diodes.

This course covers the numeral system and binary calculations, encoding, logical theory, all types of combinational logic circuit, flip flop logical theory, memory system, input-output device, D/A & A/D tranformation, digital system, structure of micro processors etc.

This course covers electron movement in vacuum, gaseous discharge, solid state electronics, electron emission, vacuum tube, phototube, discharge tube, semi conductor and PN junction, transistor and integrated circuit.

This course covers various phenomenon of electricity and magnetism. Main areas of study include Vector understanding, electric and magnetic fields in vacuum & media, boundary conditions, electromagnetic induction, and maxwell equation.

This course deals with the relationship between voltage and currents, basic principles of circuits, closed circuits and nodal equations, Laplace transformation and circuit equation transient deviation, impulse response, and RLC filter theory.

By using the combinational and sequential logic circuit theories, study on the movement features of logic circuits will be conducted through experiments on basic logic gates, Mux/Demux, Adder, Decoder, Counter and Register.

This course covers the numeral system and binary calculations, encoding, logical theory, all types of combinational logic circuit, flip flop logical theory, memory system, input-output device, D/A & A/D tranformation, digital system, structure of micro processors etc.

This course covers electron movement in vacuum, gaseous discharge, solid state electronics, electron emission, vacuum tube, phototube, discharge tube, semi conductor and PN junction, transistor and integrated circuit.

This course covers various phenomenon of electricity and magnetism. Main areas of study include Vector understanding, electric and magnetic fields in vacuum & media, boundary conditions, electromagnetic induction, and maxwell equation.

This course deals with the relationship between voltage and currents, basic principles of circuits, closed circuits and nodal equations, Laplace transformation and circuit equation transient deviation, impulse response, and RLC filter theory.

This course introduces the basic experimental and measuring equipment regarding the structures and design of analog and digital circuits, as well as research on the usage and operation of high tech electronic facilities.

This course covers the basics of diode and transistor circuits, MOSFET, Bias stability, small signal analysis, power amplifier, feedback and oscillator, theory and application of operational amplifier and design of applied circuits, and the design of passive and active filters.

This course covers continuous signals, discrete signals and their systems, and conducts analysis on each system using differential equations. In order to understand the systems, Laplace and Z transformation will be studied, as well as Fourier series and transform regarding continuous signals and discrete signals.

This course studies the features of electromagnetic radiation by applying the basic principles of electromagnetism. Various structures of transmission lines and characteristics of radio waves will also be examined including related current issues.

This course is designed to practice the concepts of alternating electric circuits through experiments, and examine basic amplifiers and the application of operational amplifiers.

This course deals with the basic principles of data communications and protocol. The main areas of study include transmission medium and signal, coding and modulation, multiplexing technology, error detection and correction, multiple access technology and related protocol.

This course aims to develop application abilities required for analog computer functions and interfacing, by studying the basic principles composing oscillators, regulators, linear amplifiers, operational amplifiers and compensating circuits, using electronic circuit device.

This course deals with basic communication theories such as signal interpretation and linear system analysis, spectrum and random process. In addition, analysis on actual communication methods such as AM, FM, PM will be conducted, as well as study on the application and theoretical analysis of PCM communication, multiple communication and data communication.

This course studies the features of electromagnetic radiation by applying the basic principles of electromagnetism. Various structures of transmission lines and characteristics of radio waves will also be examined including related current issues.

This course deals with hardware structures and software design of computers. Main subjects include the structure of computing and controlling device, memory management, input-output control, basic system program design etc. In addition, we will learn about controlling the system using microprocessors. Simple applications of numerical systems and codes, calculation methods, central computing and peripheral device, micro computer program technique will be examined.

This course deals with the basic principles for CMOS VLSI integrated circuit design. Main areas of study include the history of integrated circuits, CMOS process outline, CMOS inverter design, CMOS static and dynamic logic circuit design theory and applications. In addition, practical exercises will be conducted regarding the design of integrated circuits using actual CMOS process variables.

This course covers the basic principle of mobile communications such as cellular system, characteristics of frequency, relay station selection, radiation pattern of antenna in use and trends of future mobile communications.

This course deals with the study of wireless communication device and system design theory in relation to radio engineering. By conducting actual design of various passive and active RF devices using commonly applied design software(ADS, HFSS, IE3D etc) and measurement instruments, this course enables students to enhance practical work skills. In addition, the course will be operated in teams, enhancing the ability to work in harmony with teammates and divide work efficiently for the successful completion of projects.

This course aims to develop the skills learned in Capstone Design 1 and apply them to the design of practical and creative engineering products with industrial value.