1st |
Major Required |
Comprehensive design task |
This course is designed for students in all four grades to complete their design projects and produce final hardware / software products by combining a lot of theoretical knowledge and experience from mechanical engineering. |
Major Elective |
Data-Driven Engineering Design |
This course covers the fundamentals of engineering design, including problem definition, conceptual design, and detailed design processes. Students will learn the basic concepts of optimal design, optimality conditions, and various optimization techniques. The course also introduces probabilistic design, Bayesian optimization, AI-based autonomous experimentation, and digital twins. A term project based on these theoretical foundations is included. |
Robot
Kinematics |
This course focuses on designing mechanical systems and mechanisms for motion generation and analyzing them kinematically. It includes a term project in which students design mechanisms and perform analyses based on what they have learned. Prerequisite knowledge of linear algebra and MATLAB is required. |
Finite
Element Method |
Basic concepts of finite element formulation, one- and two-dimensional shape functions, finite element analysis of one-dimensional and two-dimensional engineering problems, and analysis of actual engineering problems using FEM. |
Rotor
Dynamics |
This course covers the operating principles and performance prediction of various rotating machines such as steam turbines, gas turbines, compressors, and pumps. It addresses design methods of rotating machinery based on mechanical dynamics and introduces practical applications in industrial fields. Prerequisite knowledge of dynamics, numerical analysis, and mechanical vibrations is required for this course. |
Computational Fluid
Dynamics |
Students will learn the basic theory of FDM, FVM, FEM and the numerical system for solving basic PDE equations of elliptical, parabolical and hyperbolic. It also teaches how to analyze PDE stability. |
Energy
System
Design |
This course introduces the concepts of various advanced energy systems. It includes a project on system design and applies engineering and economic analysis methods to evaluate overall performance. |
Application Heat Transfer |
Third year 2nd Learn about free convection, boiling and condensation points, heat exchangers, and copying that have not been taught in heat transfer. We also use the knowledge we have learned from heat transfer and applied heat transfer to design thermal systems. |
Turbo Machine |
This course focuses on the principles and performance of fluid machinery, fluid mechanical design based on mechanics, and introduction to industrial applications. Includes term projects to design compressors and pumps. |
Fundamentals Of
Engineering |
This course provides fundamental academic knowledge and background in physics, solid-state physics, and chemistry to understand the functional properties of nanomaterials. In addition, students will gain knowledge and hands-on experience with characterization and analysis equipment such as electron microscopes, optical microscopes, and atomic force microscopes. |
Surface Engineering |
This course deals with surface engineering that is the basis of micro and nanotechnology. We aim to understand surface phenomenon and function using measurement and analysis method. |
CAD/CAM |
Learn CAD system to express solid model. In particular, you will learn solid model representations of free curves and surfaces. Includes term projects using CAD skills learned during the semester. |
Precision
Mechanical
Measurement |
It covers the fundamentals of precision measurement, including temperature and pressure measurement. For this purpose, Fourier analysis is discussed, and students learn Fourier series, Fourier integrals, and Fourier transforms, as well as solution methods for partial differential equations. |
Mechatronics |
PLC programming, Arduino programming, and mechatronics systems. In a group of 2-3 students, two projects must be done using Arduino. |
Smart
Factory |
This course covers the basic concepts of smart factories and production automation, including the components of automation systems such as sensors, controllers, actuators, and networks. Students will also learn about numerical control, robotics, industrial logic control, and computer-aided manufacturing (CAM). |
Hydraulic Engineering |
This course focuses on the theory of design, analysis and application of fluid power systems. Based on the basic knowledge of mechanical engineering in general and the contents of hydraulic engineering, we will carry out the term project. |
Human-Machine Interaction |
It is a course to explore and learn about the future machine industry through various assignments and term projects as well as lectures on human-machine interaction. |
Power
Plant
System Engineering |
This course introduces types of nuclear power plant (NPP) systems designed based on the Rankine cycle for power generation. It also provides fundamental knowledge of the design and analysis of plant components such as steam generators, pressurizers, reactor coolant pumps, condensers, and feedwater heaters. |
Nuclear
System
Engineering |
PWR, PHWR, BW, GCR, SMR, FBR and various analysis methods such as reactor, steam generator, pressurizer, reactor coolant pump and turbine.
|
Reactor Experiment |
This course involves participation in material testing, radiation testing, and reactor operation testing using research reactors, which are conducted at facilities of a national research institute. |
2nd |
Major Required |
Graduation thesis |
One of the requirements for graduation, you will learn how to write a paper. I will write a paper based on the content of the comprehensive design project of the first semester of the fourth grade. |
Major Elective |
Post Capstone
Design |
In this course, students who successfully demonstrated the feasibility of the design from the Capstone Design Project can enhance their design project to move forward including patent application of the novel concept, working prototype fabrication, and prep. for venture business start-up. Students should use rapid-prototyping technologies and also should prove that the prototype meet certain test standards. |
Undergraduate
Independent
Studies
(II) |
This course is primarily based on self-study, allowing students to learn a series of processes such as applying existing knowledge and skills, acquiring new knowledge, solving problems, and proposing new solutions to problems. |
Optimal Design |
Based on the theory learned in linear algebra and numerical analysis, it is a course that learns how to define engineering design problems in mathematical form and find design variables with optimal performance. |
Engineering
Design of
Rechargeable
Batteries |
In this course, fundamentals of modern rechargeable battery systems are first discussed. Then, designing and manufacturing batteries’ components will be covers. This course also provides various theories that concerns evaluation and prediction of batteries’ performance and safety. Completion of this course will allow you to enhance understandings on the electrochemical energy storage systems and their applications. |
Failure
Prevention
Engineering |
This course offers an opportunity for ME and related major senior-level students to learn about new design concepts and the maintenance technologies for safety/quality-critical structural integrities in various industries. They include aerospace/space, offshore, infra, transportation, and many other heavy industries. It deals with a variety of diagnostic and prognosis topics, including advanced materials such as composites, mechanical behavior of materials, fatigue and fracture, NDE (Nondestructive Evaluation), or SHM (Structural Health Management). |
Noise Vibration |
Grade 3 1st This is an intensive course on mechanical vibration of sound, such as acoustic physics, noise propagation, noise calculation, room acoustics and noise prevention technology. |
Renewable Energy
Engineering |
The course will address and discuss in detail the energy related to renewable engineering through the lecture, which covers the solar cell/heat, wind power generation, ocean/offshore energy, geothermal energy, hydropower, fuel-cell, etc. In addition, the latest advanced environmental-friendly energy technologies will be discussed through reviewing and presenting recent journal papers. Students will gain advanced techniques related to renewable energy systems and a thorough understanding of the potentials of these emerging technologies and future trends of advanced mechanical engineering. |
Energy Semiconductor
Engineering |
Introduction to energy semiconductor materials, atomic electron configuration, basic quantum mechanics, energy bands, thermodynamic equillibrium semiconductor, carrier transportation, carrier generation and recombination, PN junction and energy band diagram, basic principle of solar cells, development of energy semiconductor materials. |
Fuel Cell Engineering |
This course deals with fuel cell power generation mechanisms based on thermodynamics, fluid mechanics, and electrochemistry, and various heat / mass transfer. The design and operating conditions of fuel cell materials, stacks and BOP systems are also briefly discussed. |
Air conditioning and
Refrigeration |
One of the graduation requirements, you will learn the writing process. Write a paper based on the content of the comprehensive design project of the first semester of the fourth grade. |
Material Molding
Mechanics |
The objective of the course is to learn the material forming process, the mechanical behavior of elastic and viscoelastic materials, the theory of forming elastic and viscoelastic materials, and the structure analysis of thin films. |
Material Dynamics |
Teaches the theory of static and dynamic behavior of materials, tensile, fatigue, creep and brittle fracture. Includes term projects for mechanical design problems with detailed requirements. |
Advanced
High
Energy
Based
Manufacturing |
This course covers the fundamental theories and processes of high-energy-based manufacturing methods, including welding, coating, and metal additive manufacturing. It also includes a term project related to these topics. |
MEMS Introduction |
Lectures and experiments are conducted to provide a practical introduction to micro-electro-mechanical systems (MEMS). Learn about MEMS materials and manufacturing methods, and introduction and overview of MEMS applications. |
Measurement System |
Understand how to measure various physical quantities, and develop measurement system design and application ability. It also covers measuring, collecting, processing, and analyzing signals. |
Artificial Intelligence System |
This course focuses on a fundamental understanding of artificial intelligence, with particular emphasis on deep neural networks (DNN). Students will learn the basic mathematics, theories, and practical techniques related to DNN, and study how to implement, train, and debug their own neural networks. |
Robotics |
This course deals with basic concepts of robot, information, intelligence and interpretation in terms of control. It includes not only lectures but also various practical time. |
Introduction
To
Medical AI Imaging |
This course covers the principles of modern medical imaging equipment and systems, such as X-ray imaging, computed tomography (CT), magnetic resonance imaging (MRI), nuclear medicine imaging, and ultrasound imaging, and also discusses the engineering issues of these systems. In addition, it introduces the principles of tomographic image reconstruction, an overview of deep learning, and its applications in medical imaging. |
Nuclear
Safety Engineering |
Basic concepts of nuclear power plant safety, problems related to nuclear accident and safety system, safety analysis method. Introduction to nuclear engineering must be taken. |
Thermal-Hydraulic System Analysis |
This course focuses on simulations of thermo-hydraulic systems with an emphasis on macroscopic and transient analysis. The MARS code is used as the simulation tool, and the course combines lectures with practical exercises. |
Nuclear Technology Seminar |
Introduction to various areas of nuclear engineering: Gen-IV systems, fusion reactors, particle accelerators, research reactors, isotope production reactors, small reactors for cogeneration, and marine reactors. |