The students learn the use and basic circuit link methods for various measuring instruments through basic experiments, which is the basics for learning of electronic engineering. And in order to understand and learn various laws and principles of basic electronic engineering, the students carry out experiments focused on various properties of electronic elements such as diode, transistor and FET.
This lecture deals with basic theories needed for physical phenomena of the elements used in electric and electronic circuits. And the students examine the physical and electric properties of semiconductor elements, which are the basics for electricity and electronic engineering, including the physical phenomena of electrons which occur inside metals and semiconductors.
This lecture focuses on understanding the basic theories related to electromagnetic phenomena mainly in a macro view, making students acquire the ability to formulate and vectorize the phenomena. Based on the basic phenomena of electricity and magnetism, the students are taught electric and magnetic field in a vacuum, boundary condition, electromagnetic induction, and the Maxwell's equations.
The students learn the basic concept of circuits, basic wave, basic circuit, solving circuit equation, and electric circuit signal analysis. Based on the Circuit Theory(1), they learn DC circuit, AC circuit, complex numbers and circuit analysis, inductively coupled circuit, Laplace Transform, Fourier Transform, and equation of state.
The students acquire the basic knowledge about logic circuit design by learning the number system, coding, logic theory, logic circuit minimization, memory unit, and in/out-put device. They also deal with the factors related to sequential logical circuit design, which include the properties of flip-flop, sequential logical circuit architecture, and the use of sequential logical circuit, including application of the circuit.
The students carry out experiments on electric properties of metals, electric wire materials, resistive materials, contact materials, thermo-couple materials, including the basic properties of insulating materials, magnetic materials, and semiconductor materials.
Based on the knowledge of Solid State Physics(1), the students need to grasp the outline of Material Science.
The students learn the energy band theory of semiconductors, diffusion and scattering process, charge transport, and the quantum effect and Interface phenomena. They also study semiconductor elements theory in order to cultivate their ability to develop new semiconductor elements, including the movement of existing semiconductor elements. This research includes the pn junction diodes, M-S junction diodes, bipolar transistors, MOSFET, and JFET.
This lecture focuses on analysis of circuit operation, in which semiconductors are used, and improve the ability to design electronic circuits. The students deal with the circuits of rectifier, amplifier circuits, and various filters, which are used in electronic elements such as diodes, transistors and operational amplifiers.
In this subject, the photophysical theories, in which the properties of light from nature are studied, are grafted onto the professional knowledge of electronic engineering, which will be used in real life of humans. The optical properties and applicable fields of the properties are dealt with by emphasizing the application fields of modern optics in which laser is used.
This lecture deals with the concept and unit of vacuum, properties of gas, including the operation principle and structure of vacuum pumps and vacuum gauge. And the students learn manufacturing process and application of electronic materials.
Learning the basic laws of thermodynamics, the students need to understand the characteristics of the subject. And then, based on what they have learned, the students study how the characteristics are formed by mixing various materials.
The lecture focuses on helping the students understand the architecture and operating principles of display elements such as TFT-LCD, OELD, PDP, and LED.
Based on the thermodynamics, the students learn about diffusion and phase diagrams intensively when they study Materials Phase Stability, which is the basic for new material design.
In this subject, the students have a chance to directly experience the researches that are in progress at the labs of professors. And then, they fabricate elements that accord with the experimental topics assigned to each lab, so that they may carry out experiments on semiconductor and new material process and investigate the properties of them.
In this subject, individual or groups of students are assigned a task. The contents of task including the theme, scope and plan will be determined by the students. The outcome evaluation criteria include the level of difficulty, sharing of roles, teamwork, sincerity, and whether the target of the task is in accordance with the major subject.
This two-semester course is about semiconductor process, in which the students learn basic theories and technologies used for semiconductor fabrication process. So, this course includes the theories and technologies related to unit processes such as crystal growth, lithography, oxidation, ion implantation, thin-film deposition process, metal interconnection process, including simulation technologies.
This course focuses on learning the basic knowledge to design VLSI. The students deal with MOS inverter operation, design rule and layout, MOS logic circuit design method, VLSI chip design methodology, VLSI design support system, and testing methods.
The students learn about principles and operation methods of various instruments used for analyzing properties of electron materials. The lecture deals with SEM, TEM, X-ray, AES, XPS, and SIMS.
The student learn about the properties of thin film materials and thin film deposition techniques.
In this subject, the students learn various dielectric materials from the basic concepts and properties to the applicable fields of dielectric substance materials.
Centering on electromagnetic theory, which is the basics for magnetic materials, the students learn the applicable fields of spintronics.
This subject introduces the compound semiconductor materials needed for photoelectric elements. And then the students learn about photoelectric elements, such as photodetector, solar battery, luminescent diode, and semiconductor laser, in which the photoelectric elements are used.