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- Graduate major in Technology and Innovation Management
- Common courses
- Liberal arts and basic science courses
- Academic unit or major
- Graduate major in Electrical and Electronic Engineering
- Instructor(s)
- Miyamoto Tomoyuki
- Class Format
- Lecture
- Media-enhanced courses
- Day/Period(Room No.)
- -
- Group
- -
- Course number
- EEE.D461
- Credits
- 2
- Academic year
- 2024
- Offered quarter
- 3Q
- Syllabus updated
- 2024/3/14
- Lecture notes updated
- -
- Language used
- Japanese
- Access Index
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Course description and aims
This lecture focuses on semiconductor photonic devices and light propagation that are useful for the design and understanding of photonic systems.
The aim of this lecture is to learn the characteristics, principles, and properties of small size light-emitting devices, and related photonic functional devices such as light receiving devices and optical modulators. Focusing on light-emitting devices, the following will be studied in detail: Types of devices, principles of light emission, static characteristics such as light output, temperature characteristics, and efficiency, and dynamic characteristics such as signal modulation, as well as important functions of light propagation and the leading edge trends in important photonic applications.
In this lecture, students learn more details and practical knowledge of photonic device technologies, such as optical and electromagnetic properties in semiconductors, and optoelectronics, that are covered in the undergraduate program.
Student learning outcomes
At the end of this course, students will be able to:
1) Explain the principle of operation of photonic devices.
2) Explain the static and dynamic characteristics of photonic devices.
3) Design basic photonic devices.
4) Explain applications of advanced photonic devices.
Course taught by instructors with work experience
| ✔ Applicable | How instructors' work experience benefits the course |
|---|---|
| Lecturer has experiences of design, fabrication, characterization, and creation of new applications of semiconductor photonic devices as a researcher. |
Keywords
photonics, optoelectronics, photonic device, light emitting device, semiconductor laser, LED, light propagation, optical waveguide
Competencies that will be developed
| ✔ Specialist skills | Intercultural skills | Communication skills | ✔ Critical thinking skills | ✔ Practical and/or problem-solving skills |
| ✔ Students acquire the professional and deployment skills that enable to research and develop the latest photonic devices and their application systems. | ||||
Class flow
Students must familiarize themselves with the topics described in the required learning section before coming to class.
Students will be given exercises related to what will be taught on that day.
Course schedule/Required learning
| Course schedule | Required learning | |
|---|---|---|
| Class 1 | Introduction to optoelectronics/photonics | Investigation of wavelength, frequency, and energy of light and photon. Survey of application cases of optoelectronics/photonics. |
| Class 2 | Fundamentals of light propagation and optical waveguides | Understanding the principles and mathematical analysis procedures of light propagation, reflection, and refraction. |
| Class 3 | Fundamentals of analysis and design of optical waveguides | Understanding the basic principles and mathematical analysis procedures of optical waveguides. |
| Class 4 | Detailes of optical waveguide and 3D waveguide | Understanding of 2D and 3D waveguide structures, and investigation of various analysis methods of light propagation. |
| Class 5 | Light loss and waveguide coupling | Understanding the various loss in the waveguide and behavior of light propagation under the complicated refractive index structure. |
| Class 6 | Output and focusing of light beam | Understanding of Huygens principle and Gaussian function. |
| Class 7 | Fundamentals, analysis and design of semiconductor light emitting devices | Investigation of size, operation current, and output power of light emission devices. |
| Class 8 | Exercises to assess students' understanding of what has been taught so far. | Confirmation of understanding level and self-evaluation of achievement of 1-7 lectures. |
| Class 9 | Wavelength, efficiency, and temperature characteristics of semiconductor light emitting devices | Investigation of the available temperature range of light emitting devices, and its restriction reasons. |
| Class 10 | Dynamic characteristics of semiconductor light emitting devices | Understanding the principles of carrier recombination and the characteristics of carrier lifetime. |
| Class 11 | Vertical cavity surface emitting lasers and their applications | Investigation of the impact of the device size miniaturization of the laser. |
| Class 12 | Emission principle of semiconductor light emitting devices | Understanding the basics of electromagnetic radiation based on the dipole, and the electronic states in crystal. |
| Class 13 | Photonic functional devices | Investigation of various dynamic functions required in photonic applications. |
| Class 14 | Advanced trends in photonic application systems using various photonic devices | Investigation of the novel photonic applications and features of photonic devices. |
Out-of-Class Study Time (Preparation and Review)
To promote effective learning, students are encouraged to spend approximately 100 minutes preparing for each lecture and another 100 minutes reviewing each lecture (including assignments) afterward.
They should do so this using the textbooks and other course materials.
Textbook(s)
None required.
Lecture using materials prepared by the instructor.
Reference books, course materials, etc.
All materials used in lectures can be found on T2SCHOLA.
[Japanese] Y. Suematsu and K. Iga, Introduction to Optical fiber communication, ISBN:978-4274220944, Ohmsha, 2017.
Assessment criteria and methods
This course assesses understanding of the principles, characteristics, and features of photonic devices and related technologies.
Students' course grades will be based on the evaluation of understanding through midterm and final reports (60%) and homework assignments for each lecture (40%).
The exercises and reports will emphasize the construction of mathematical equations based on the theory and the graphical representation of the results of the analysis of these equations based on numerical methods.
Related courses
- EEE.D531 : Fundamentals of Light and Matter IIa
- EEE.D532 : Fundamentals of Light and Matter IIb
- EEE.D533 : Fundamentals of Light and Matter IIc
- EEE.D431 : Fundamentals of Light and Matter I
- EEE.S461 : Optical Communication Systems
- EEE.D331 : Optical and Electromagnetic Property in Semiconductors
- EEE.E202 : Electricity and Magnetism II
- EEE.S361 : Opto-electronics
- EEE.D211 : Semiconductor Physics
- EEE.D201 : Quantum Mechanics
Prerequisites (i.e., required knowledge, skills, courses, etc.)
Students must have successfully completed Quantum Mechanics (EEE D201), Semiconductor Physics (EEE D211), and Electromagnetism (EEE E201, EEE E202, EEE E211) or have equivalent knowledge.
Students have been desired to have the following knowledge and skills: Optical and Electromagnetic Property in Semiconductors (EEE D331), Opto-electronics (EEE S361)
Contact information (e-mail and phone) Notice : Please replace from "[at]" to "@"(half-width character).
Tomoyuki Miyamoto, tmiyamot[at]pi.titech.ac.jp, 045-924-5059
Office hours
Contact by e-mail in advance to schedule an appointment.
