For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| ECE5422 | Thin Film Technology Applications | 3 | 6 | Major | Master/Doctor | 1-4 | English | Yes | |
| Thin films are unique properties significantly different from the corresponding bulk materials as a result of their physical dimensions, geometry, and nonequilibrium microstructure. The lecture reviews the properties of thin films and offers the various method of thin film growth and characterization. This lesson applies to many valuable electronic devices such as resistor, inductor, capacitor, thin film transistor, VLSI, sensor, and memory device. | |||||||||
| ECE5423 | Semiconductor Devices | 3 | 6 | Major | Master/Doctor | 1-4 | English | Yes | |
| Semiconductor devices discusses the physical characteristics of semiconductor, and the theory and application of pn diode, MOS devices, and BJT which are the core devices to make moder | |||||||||
| ECE5423 | Semiconductor Devices | 3 | 6 | Major | Master/Doctor | 1-4 | Electrical and Computer Engineering | English | Yes |
| Semiconductor devices discusses the physical characteristics of semiconductor, and the theory and application of pn diode, MOS devices, and BJT which are the core devices to make moder | |||||||||
| ECE5429 | Topics on Properties of Electronic Engineering Materials | 3 | 6 | Major | Master/Doctor | 1-4 | - | No | |
| By the information of carrier movements in the periodic arrangement of atoms, the lecture explains the conduction mechanisms in a solid matter. This lecture also deal with the thermal properties such as specific heat, thermal conduction, thermal expansion, and other thermal induced effect. Some other topics such as Brillouin zone, effective mass, conductivity, and carrier movement will be treated in this course work. | |||||||||
| ECE5461 | Lower Power VLSI Design | 3 | 6 | Major | Master/Doctor | 1-4 | - | No | |
| This course covers process/device lower power design, circuit design ; lower power DRAM circuit design, Lower power high-level (architecture/logic) synthesis ; power-driven layout synthesis. | |||||||||
| ECE5461 | Lower Power VLSI Design | 3 | 6 | Major | Master/Doctor | 1-4 | Electrical and Computer Engineering | - | No |
| This course covers process/device lower power design, circuit design ; lower power DRAM circuit design, Lower power high-level (architecture/logic) synthesis ; power-driven layout synthesis. | |||||||||
| ECE5467 | Analog IC Design | 3 | 6 | Major | Master/Doctor | 1-4 | English | Yes | |
| This course provide a simulation technique and CMOS device modeling for analog design. Based on the basic design technique, the course cover the following subjects for memory design, Current Mirror Circuit, OP-Amp design, Reference Circuit Design, Charge Pump Design, PLL/DLL design and I/O Buffer design. | |||||||||
| ECE5467 | Analog IC Design | 3 | 6 | Major | Master/Doctor | 1-4 | Electrical and Computer Engineering | English | Yes |
| This course provide a simulation technique and CMOS device modeling for analog design. Based on the basic design technique, the course cover the following subjects for memory design, Current Mirror Circuit, OP-Amp design, Reference Circuit Design, Charge Pump Design, PLL/DLL design and I/O Buffer design. | |||||||||
| ECE5471 | Analog/Mixed-Signal Design | 3 | 6 | Major | Master/Doctor | 1-4 | Korean | Yes | |
| Analog/mixed-signal design treats interface circuit design techniques for analog/digital data conversion and filtering which are useful for embedding in the SoC. | |||||||||
| ECE5471 | Analog/Mixed-Signal Design | 3 | 6 | Major | Master/Doctor | 1-4 | Electrical and Computer Engineering | Korean | Yes |
| Analog/mixed-signal design treats interface circuit design techniques for analog/digital data conversion and filtering which are useful for embedding in the SoC. | |||||||||
| ECE5511 | Advanced Optoelectronics | 3 | 6 | Major | Master/Doctor | 1-4 | English | Yes | |
| Advanced optical electronics course. Review of nonlinear optics, second harmonic generation, parametric amplification and oscillation, fluoresence, third-order otpical nonlinearity, stimulated Raman and Brillouin scattering, phase conjugation, photorefractive beam coupling, Q-switching and mode lockingof lasers. | |||||||||
| ECE5511 | Advanced Optoelectronics | 3 | 6 | Major | Master/Doctor | 1-4 | Electrical and Computer Engineering | English | Yes |
| Advanced optical electronics course. Review of nonlinear optics, second harmonic generation, parametric amplification and oscillation, fluoresence, third-order otpical nonlinearity, stimulated Raman and Brillouin scattering, phase conjugation, photorefractive beam coupling, Q-switching and mode lockingof lasers. | |||||||||
| ECE5515 | Nanophotonics | 3 | 6 | Major | Master/Doctor | 1-4 | - | No | |
| Nanophotonics, defined by the fusion of nanotechnology and photonics, is a multidisciplinary field which deals with the interaction between a matter and photons in nano-meter scaled space. In this lecture, we will deal with various nanophotonic applications, including plasmonics, photonic crystal, quantum dots, nanolithography, and so forth. | |||||||||
| ECE5521 | Numerical Analysis of Electromagnetic Field | 3 | 6 | Major | Master/Doctor | 1-4 | - | No | |
| Numerical solutions of electromagnetic field are calculated using Finite Element Methods. (FEM) The basic theories of variational method, Dirichlet and Neumann boundary conditions, Rayleigh- Ritz method, and Garlerkin's method are surveyed. Finite element idealizations, discretization, and equation assembly processes are explored. FEM applies to electro - magnetostatics and the students are strongly encouraged to calculate electro- magnetic fields of many different boundary conditions, using finite element packages. | |||||||||
| ECE5521 | Numerical Analysis of Electromagnetic Field | 3 | 6 | Major | Master/Doctor | 1-4 | Electrical and Computer Engineering | - | No |
| Numerical solutions of electromagnetic field are calculated using Finite Element Methods. (FEM) The basic theories of variational method, Dirichlet and Neumann boundary conditions, Rayleigh- Ritz method, and Garlerkin's method are surveyed. Finite element idealizations, discretization, and equation assembly processes are explored. FEM applies to electro - magnetostatics and the students are strongly encouraged to calculate electro- magnetic fields of many different boundary conditions, using finite element packages. | |||||||||