| Course title | |||||
| 材料電磁気学 [Electromagnetics for material science] | |||||
| Course category | technology speciality courses,ets. | Requirement | Credit | 2 | |
| Department | Year | 2~4 | Semester | Spring | |
| Course type | Spring | Course code | 022304 | ||
| Instructor(s) | |||||
| 臼井 博明 [USUI Hiroaki] | |||||
| Facility affiliation | Faculty of Engineering | Office | Bldg. 4-241 | Email address | |
| Course description |
| In the first part, learn the Gauss' theorem and Poisson's equation to understand electrostatic phenomena. Give an understanding on the relationship between electric charge, electric field, and electrical potential. In the second part, learn the relationship between electrical current and magnetic field. Understand that the electric current generates magnetic field, and then magnetic field generates electromotive force. |
| Expected Learning |
|
1. Solve the equation to obtain electric field using Gauss' theorem. 2. Solve the equation to obtain electrical potential using Poisson's equation. 3. Describe the relations between electric charge, electric field and electrical potential. 4. Describe the equation of force that is exerted to a current or a moving charge in a magnetic field. 5. Calculate the magnetic field using Biot-Savart law 6. Calculate the magnetic field using Ampere's law 7. Calculate the electromotive force in a moving or transforming circuit |
| Course schedule |
|
Part 0, Orientation (1) General introduction and review of fundamentals Part 1, Electrostatic Phenomena (2) Coulomb's law and line of electric force (3) Gauss' theorem (4) Electrical potential and electrostatic capacitance (5) Poisson's equation (6) Metal and insulator Part 2, Electrical Current and Magnetic Field (7) Lorentz force (8) Biot-Savart law (9) Gauss' theorem of magnetic field and magnetism (10) Ampere's law Part 3, Electromagnetic induction (11) Lenz's law (12) Electric generator (13) Self induction and mutual induction. Transformer. Part 4, Electromagnetic wave (14) Displacement current (15) Maxwell's equation and electromagnetic wave |
| Prerequisites |
|
Requires basic mathematics on vector, differenciation and integration Requires basic understanding of mechanical physics such as equation of motion and potential energy The topics of dielectrics and electrical circuit are rendered to the laboratory class |
| Required Text(s) and Materials |
| In Japanese |
| References |
| Assessment/Grading |
| 85% final examination + 15% weekly attendance and exercise |
| Message from instructor(s) |
|
Many students have an impression that the electromagnetic theory is difficult to understand due to frequent use for differential and integral mathematics. However, it is important to give a graphical image of the phenomena before resorting to the mathematical equations. This subject is indispensable to understand the basic properties of materials and molecules. In addition, the electromagnetic phenomena are found in various aspects of our daily life. |
| Course keywords |
| Gauss' theorem, Poisson's equation, Ampere's law, electromagnetic induction |
| Office hours |
| Remarks 1 |
| Remarks 2 |
| Related URL |
| Lecture Language |
| Language Subject |
| Last update |
| 3/22/2017 11:08:07 AM |