| Course title | |||||
| フォトニクス [Photonics] | |||||
| Course category | technology speciality courses,ets. | Requirement | Credit | 2 | |
| Department | Year | 3~4 | Semester | 1st | |
| Course type | 1st | Course code | 023608 | ||
| Instructor(s) | |||||
| 室尾 和之 [MUROO Kazuyuki] | |||||
| Facility affiliation | Faculty of Engineering | Office | afjgxte/L1151 | Email address | |
| Course description |
|
Modern photonics has been developed based on "Optics" and "Laser science" in recent years, which are now applied to wide range of science and engineering, such as optical science, optical telecommunication, optical recording, and semiconductor processing. This lecture is mainly focused on "Geometrical optics" and "Wave optics", the former of which provides intuitive understanding of light based on the concept RAY, and the latter provides quantitative understanding of light based on the concept WAVE. This lecture is based on the lectures, "Physics of Waves", and "Electrodynamics I, II". |
| Expected Learning |
|
The aim of this course is to understand physical properties of light based on "Geometrical optics" and "Wave optics" and to explain physically these concepts. Corresponding criteria in the Diploma Policy: See the Curriculum maps. |
| Course schedule |
|
Week 1: Geometrical optics: Law of reflection, law of refraction (Snell's law) and Fermat principle Week 2: Geometrical optics: Paraxial (Gaussian) optics, lens, ray diagram Week 3: Geometrical optics: Law of refraction and lensmaker's equation Week 4: Geometrical optics: Properties of a lens 1, concave and convex lenses, focal length, real and virtual images Week 5: Geometrical optics: Properties of a lens 2, aperture, 1/F number, depth of focus, depth of field, and Seidel aberrations Week 6: Wave optics: Electromagnetic wave, Maxwell's equations, wave equation, and plane wave Week 7: Wave optics: Energy density and energy flux density (Poynting vector) Week 8: Wave optics: Law of reflection and law of refraction based on wave optics (Huygens-Fresnel principle) Week 9: Wave optics: Reflectance and transmittance, P-wave and S-wave Week 10: Wave optics: Single-slit diffraction, Fraunhofer Diffraction Week 11: Wave optics: Circular aperture diffraction, Airy disk, Rayleigh criterion Week 12: Wave optics: Multi-slit diffraction, grating Week 13: Wave optics: Two-beam interference, Young double slit, Michelson interferometer, Mach-Zehnder interferometer, Sagnac interferomete Week 14: Wave optics: Multi-beam interferometer, Fabry-Perot interferometer Week 15: Summary, Final examination |
| Prerequisites |
|
Electrogmatnetism, Oscillation and wave, Quantum electronics Preparation and review of related topicsIn addition to 30 hours that students spend in the class, students are recommended to prepare for and revise the lectures, spending the standard amount of time as specified by the University and using the lecture materials. |
| Required Text(s) and Materials |
| References |
| Hecht "Optics" |
| Assessment/Grading |
| Quiz in every on-line lecturer and homework. These account for 70% and the final exam for 30% of the performance. |
| Message from instructor(s) |
| Course keywords |
| Geometrical optics, Wave optics, lens, light wave, interference, diffraction |
| Office hours |
| Mon. 12:00-13:00 (Email: muroo@cc.tuat.ac.jp) |
| Remarks 1 |
| Remarks 2 |
| Related URL |
| Lecture Language |
| Japanese |
| Language Subject |
| Last update |
| 4/24/2020 8:50:08 AM |