For more details on the courses, please refer to the Course Catalog
Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
---|---|---|---|---|---|---|---|---|---|
EME4914 | FutureCarIntelligentSystem | 3 | 6 | Major | Bachelor/Master | - | No | ||
This course provides an introduction and overview of the control systems for future vehicles. After learning about the technology overview of smart cars or self-driving cars, students learn the basic concepts and core technology for perception, decision, and control required for autonomous driving control. Students will derive the vehicle's longitudinal and lateral dynamic equations and use them to study the characteristics of the control systems. They will learn about advanced cruise control, a representative longitudinal control system, and also cover the control characteristics of the lateral steering control system. In addition, the course also covers an overview of virtual driving simulators and vehicle simulation technology that can validate control system performance in a virtual environment. | |||||||||
EME4914 | FutureCarIntelligentSystem | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | - | No | |
This course provides an introduction and overview of the control systems for future vehicles. After learning about the technology overview of smart cars or self-driving cars, students learn the basic concepts and core technology for perception, decision, and control required for autonomous driving control. Students will derive the vehicle's longitudinal and lateral dynamic equations and use them to study the characteristics of the control systems. They will learn about advanced cruise control, a representative longitudinal control system, and also cover the control characteristics of the lateral steering control system. In addition, the course also covers an overview of virtual driving simulators and vehicle simulation technology that can validate control system performance in a virtual environment. | |||||||||
EME4915 | Energy materials and analysis | 3 | 6 | Major | Bachelor/Master | Korean | Yes | ||
This course deals with a subject regarding recent advanced materials of energy storage system. The first part covers the materials for energy storage using electrochemical devices (batteries and supercapacitors), extending to electric vehicles as future mobilities. Moreover, representative analysis methods to energy storage devices are also covered to understand the basic principle of cell design and configuration. | |||||||||
EME4915 | Energy materials and analysis | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | Korean | Yes | |
This course deals with a subject regarding recent advanced materials of energy storage system. The first part covers the materials for energy storage using electrochemical devices (batteries and supercapacitors), extending to electric vehicles as future mobilities. Moreover, representative analysis methods to energy storage devices are also covered to understand the basic principle of cell design and configuration. | |||||||||
EME4916 | Microfabrication and Applications of Biochip | 3 | 6 | Major | Bachelor/Master | - | No | ||
In this course, students will delve into the intricate world of biochip fabrication and explore a multitude of applications that leverage this cutting-edge technology. Biochips serve as the foundational platform for a wide range of biological sample manipulation, analysis, and detection methods. They are instrumental in simulating organs, facilitating embedded and wearable medical devices, and driving innovation in the field of biotechnology. Throughout this course, students will gain a solid foundation in key areas such as semiconductor processes, biosensing techniques, and cell culture technologies. These fundamental skills will enable students to integrate and apply their knowledge in various domains, including cell biology, toxicology, pharmacy, forensic science, and disease diagnosis, with a specific focus on conditions such as cancer. By the end of the course, students will be equipped with the expertise to contribute to the dynamic field of biochip technology and its diverse applications in the realm of life sciences and healthcare | |||||||||
EME4916 | Microfabrication and Applications of Biochip | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | - | No | |
In this course, students will delve into the intricate world of biochip fabrication and explore a multitude of applications that leverage this cutting-edge technology. Biochips serve as the foundational platform for a wide range of biological sample manipulation, analysis, and detection methods. They are instrumental in simulating organs, facilitating embedded and wearable medical devices, and driving innovation in the field of biotechnology. Throughout this course, students will gain a solid foundation in key areas such as semiconductor processes, biosensing techniques, and cell culture technologies. These fundamental skills will enable students to integrate and apply their knowledge in various domains, including cell biology, toxicology, pharmacy, forensic science, and disease diagnosis, with a specific focus on conditions such as cancer. By the end of the course, students will be equipped with the expertise to contribute to the dynamic field of biochip technology and its diverse applications in the realm of life sciences and healthcare | |||||||||
EME4917 | Robot Operating System and Its Applications | 3 | 6 | Major | Bachelor/Master | - | No | ||
Due to rapid growing need of robot, the developing procedure of robot needs to be systematic through the use of robot software platform. This lecture is to introduce a representative software platform, robot operating system (ROS), and to provide the experience to apply ROS for robot development. The contents of this lecture include the introduction of ROS, the robot definition method for ROS and robot design, the robot simulation (i.e, Gazebo) based on ROS, and trajectory planning and basic control method. | |||||||||
EME4917 | Robot Operating System and Its Applications | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | - | No | |
Due to rapid growing need of robot, the developing procedure of robot needs to be systematic through the use of robot software platform. This lecture is to introduce a representative software platform, robot operating system (ROS), and to provide the experience to apply ROS for robot development. The contents of this lecture include the introduction of ROS, the robot definition method for ROS and robot design, the robot simulation (i.e, Gazebo) based on ROS, and trajectory planning and basic control method. | |||||||||
EME4918 | Hydrogen Energy Engineering | 3 | 6 | Major | Bachelor/Master | Korean | Yes | ||
This course introduces the basic principles of hydrogen energy engineering (production, storage, transportation, utilization), a key element for achieving carbon neutrality. To understand electrochemical energy conversion systems such as batteries, fuel cells, and supercapacitors, the fundamental theory such as thermodynamics, reaction engineering, electrochemistry, will be studied. In particular, the course covers the basic theory, performance evaluation, modeling, materials, and design of fuel cells, which directly convert the chemical energy of hydrogen into electrical energy. Based on this, currently commercialized systems and technologies at the research and development stage that will be introduced in the future are presented and discussed. Students can gain an in-depth understanding of the value chain of hydrogen energy and learn the theory of key elements in the hydrogen economy. | |||||||||
EME4918 | Hydrogen Energy Engineering | 3 | 6 | Major | Bachelor/Master | Mechanical Engineering | Korean | Yes | |
This course introduces the basic principles of hydrogen energy engineering (production, storage, transportation, utilization), a key element for achieving carbon neutrality. To understand electrochemical energy conversion systems such as batteries, fuel cells, and supercapacitors, the fundamental theory such as thermodynamics, reaction engineering, electrochemistry, will be studied. In particular, the course covers the basic theory, performance evaluation, modeling, materials, and design of fuel cells, which directly convert the chemical energy of hydrogen into electrical energy. Based on this, currently commercialized systems and technologies at the research and development stage that will be introduced in the future are presented and discussed. Students can gain an in-depth understanding of the value chain of hydrogen energy and learn the theory of key elements in the hydrogen economy. | |||||||||
EME5066 | Independent Study on the Master Student in Mechanical EngineeringⅠ | 3 | 0 | Major | Master/Doctor | 1-4 | Korean | Yes | |
This course is for the graduate student for the master course in the department of mechanical engineering. The student performs the research on the topic of his own with his advisor. | |||||||||
EME5067 | Independent Study for the Master Student in Mechanical EngineeringⅡ | 3 | 0 | Major | Master/Doctor | 1-4 | Korean | Yes | |
This course is for the graduate student for the master course in the department of mechanical engineering. The student performs the research on the topic of his own with his advisor. | |||||||||
EME5145 | Advanced Engineering Mathematics | 3 | 6 | Major | Master/Doctor | 1-8 | - | No | |
The goal of this course is to provide a group of mathematical tools that are essential to solve various problems in general areas of mechanical engineering. These tools are to be applied to realistic problems through analytical methods and computational algorithms. In a framework of transformation and approximation, several familiar concepts are explained systematically for a deeper understanding. Students will learn how to model, how to solve, and how to interpret and evaluate the result, which are all about engineering mathematics. | |||||||||
EME5168 | Advanced Structural Mechanics | 3 | 6 | Major | Master/Doctor | 1-4 | - | No | |
Structural mechanics deals with the stress and strain, which is occurred in inside of structure when the external load is applied to the structure. This lecture is based on structural mechanics, and contains advanced contents of the structural mechanics such as stress transformation in 2D & 3D stress state, magnitude and direction of principal stress in 2D &3D stress state, stress analysis using stress function, deformation and impact analysis using energy method, indeterminate problem which cannot be solved by static equilibrium conditions, structure strength analysis which is under the complex load, life evaluation of structure which is under the fatigue load. Also, ability to design of structure will be developed through solving the various examples about geometry of structure, material properties et al | |||||||||
EME5170 | Structural Elasticity | 3 | 6 | Major | Master/Doctor | 1-4 | - | No | |
A study on elastic behaviors of machine-structures subjected to various types of load will be conducted based on two dimensional stress functions. Analytically exact solutions for both stress and displacement fields of the given mechanical structures will be mathematically derived and also physically interpreted. |