Educational Courses
Educational Courses
| Year-seme | Class | Subject | Introduction |
|---|---|---|---|
| 1-first | major | introduction of automotive engineering |
This course teaches about the structure and role of each part of an automobile. The first part explains the engine of an automobile. It includes an explanation of the automobile engine and power trains for smooth operation. It also describes various efforts to reduce exhaust gas and to improve fuel efficiency. The second part explains the chassis parts of an automobile. Those are the braking, steering, and suspension systems. It studies the development of various parts to improve vehicle safety and ride comfort. This course also provides an overview of electric vehicles, batteries, and autonomous cars. |
| 1-first | major | linear algebra | Topics include scalar, vector and matrix. Also, the solving methods for simultaneous equations and vector space, using the calculation algorithm of determinant and matrices, are introduced. |
| 1-second | major |
python |
The goal is to increase students' understanding of the Python language and improve their practical skills. In the beginning of the lecture, the course is designed to acquire basic knowledge of Python. Based on this, developing program writing processes and practical application. Midterm and final exams are evaluated through descriptive tests, practical tests, and assignments. Attendance is very important as it is conducted in parallel with practical training, and there is no need to complete prerequisite courses as it is a major basic course. |
| 1-second | major | engineering mathematics | Topics include differential equations, Laplace transform, Fourier series, Fourier transform, matrix, determinant and vector. In addition, this course enhances application ability through computer simulation project. |
| 2-first | major | material mechanics | The course of material mechanics understands the relationship between the load acting on a deformable body made of a given material and the resulting deformation, and the relationship between the load acting on a deformable body and the resulting stress. In addition, we examine the relationship between stress and strain for various conditions and materials, and learn the process of determining the size of a member that supports the load when conditions for stress and strain are given. |
| 2-first | major | statics | Statics is the study of methods for quantifying the forces between bodies. Forces are responsible for maintaining balance and causing motion of bodies, or changes in their shape. Motion and changes in shape are critical to the functionality of artifacts in the man-made world and to phenomena in the natural world. |
| 2-first | major | electrics and electronics | Student will study about fundamental concepts of Electricity (Current, Energy, Voltage, Power) and most important electronic components (Resistor, Capacitors, Diodes, etc). Also they will learn about the main laws governing currents and voltages in circuits (Ohm’s law, Kirchhoff’s laws, etc) |
| 2-first | major | Laboratory for electrics and electronics | This Lab provides a comprehensive introduction to the electronic properties of semiconductors, technology, the theories and practices of the most important electronic devices, and their impacts on the performance of integrated circuits. The Lab also provides a practical perspective on electronic devices. |
| 2-second | major | CAD basic | The method of drawing up is an important and basic field used throughout the industry, such as machinery, architecture, ships, and aviation. Learn programs to create them and learn techniques to effectively create drawings. |
| 2-second | major | Dynamics | Most mechanical systems perform a function by moving. In order to design and manufacture such a moving mechanical system, it is necessary to understand the movement of the mechanical system. Dynamics analyzes the motion of an object. It can be applied to the design of mechanical systems by learning the principles and applications of displacement of mass points and rigid bodies, velocity, acceleration and the force acting on an object, the relationship between mass, work energy, impact force, and momentum. educate to be able to. |
| 2-second | major | C++ language | The C++ language is an object-oriented programming language built as an extension of the C language. It contains most of the features of C, so it is easy to learn and suitable for system programming, as well as object-oriented programming, with features such as classes, operator duplication, and virtual functions. |
| 2-second | major | thermodynamics | Thermodynamics is the study of the relations between heat, work, temperature, and energy. The laws of thermodynamics describe how the energy in a system changes and whether the system can perform useful work on its surroundings. |
| 3-first | major | Microprocessor experiment | Microcontroller Firmware technology is a core technology that realizes automation of robots, drones, and self-driving cars, which are the basis of the 4th industrial revolution, and is widely used in practice as a dedicated control device in industrial settings. Using a microcontroller, it is possible to configure a system that receives input signals from sensors and drives and controls them with various actuators or measures and monitors. The overall contents of control programming are organized in groups of two to learn through C programming practice. |
| 3-first | major | 3D CAD | Considering that most of the production of goods is practically done by CAD, CAD has the vitality to evolve along with the development of science and technology. This lecture is recommended for students who want to learn the basics of CATIA, one of the main programs of 3D CAD, in a short time. As the contents of CATIA among the wide range of 3D CAD are lectured in a limited time, the more in-depth contents are practiced directly by referring to the example drawings presented in each chapter. |
| 3-first | major | digital circuit experiment | The goal of this subject is to understand the differences between analog circuits and digital circuits through number systems and base conversion, understand digital systems through logic gates, boolean algebra, and logic circuits, and understand operation characteristics through experiments. |
| 3-first | major |
fluid mechanics |
By learning the basic theories and basic equations of general fluids and the flow of fluids, the understanding of various phenomena of fluid flow is enhanced. Through practice of fluid analysis based on statics and dynamics, the ability to apply engineering to physical systems is cultivated. In particular, by learning related practical contents using basic theories, the foundation of hydrology and hydraulics is sought to be established in the future. |
| 3-second | major | control engineering | Control engineering is the basis of mechatronics technology and automation technology. In order to solidify the basic concept of automatic control, mathematical modeling of linear dynamic systems and the analysis and design of feedback controllers can be acquired. Also, through computer simulation, basic concepts and control theories can be confirmed. |
| 3-second | major |
vehicle chassis |
Automobiles can be broadly divided into chassis systems and body frame. The chassis system consists of an engine, powertrain, suspension, braking, and steering. These devices affect the vehicle's fuel efficiency, harmful exhaust emissions, safety, stability, steering, and ride quality. Each device must be designed and controlled individually and integratedly. This course will cover the structure and role of each device. It will also cover how they should be designed in electric vehicles. |
| 3-second | major | vehicle sensors |
Students learn the basics of the overall field of measurement, characteristics of sensors, signal processing technology, digital measurement systems, and measurement response characteristics. Based on this, they analyze cases of actually applied measurement systems to learn the ability to design and apply measurement systems in industrial sites. In particular, they learn how to design a smart automotive system using measurement that applies the Internet of Things (IoT). |
| 3-second | major | actuator system | This course deals with the basic principles and control of various actuators will be studied. Also, based on this, students develop the ability to design mechatronics systems composed of sensors, measurement, system modeling, communication, and controllers. |
| 4-first | major |
heat transfer |
Heat transfer refers to the movement of heat energy between two objects. Heat always moves from a place of high temperature to a place of low temperature through conduction, convection, and radiation. This subject covers the basics of heat transfer, which occurs in various ways. It also explains how to predict and interpret heat transfer and heat loss based on theory, and studies the importance of heat transfer in industry. |
| 4-first | major | Capstone Design 1 | This course is for solving engineering problems using the major knowledge learned up to the 3rd year. Students select one of the various engineering problems, go through the process of recognizing the problem, defining the problem, and evaluating ideas to produce a final prototype. Based on this, they write an interim report for their graduation thesis. |
| 4-second | major |
autonomous vehicle |
An autonomous vehicle is a vehicle that recognizes its surroundings without driver intervention, judges driving conditions, and controls the vehicle to drive to a given destination on its own. The concept of autonomous driving originated in Germany in the 1960s, and autonomous buses and taxis are currently being tested or commercialized in Korea, China, Unite States and so on. This course introduces and learns various design methods and control technologies for developing autonomous vehicles. |
| 4-second | major | Capstone Design 2 | This course is for solving engineering problems using the major knowledge learned up to the 3rd year. Completing Capstone Design 1, complete the manufactured product, produce a final prototype, and write a graduation thesis. In addition, through individual interviews with students, consultations on future careers are conducted, and various ways to solve problems are sought through team meetings. |