Photonics 1100-3INZ14

https://drive.google.com/drive/folders/1MkBf0TzcTa-63Wi2u62OXezjqMfBkuk6

The lecture covers the basics of photonics.
Program:
- overview of basic terms, equations, and approximations in optics.
- Linear systems; fundamentals of diffraction theeory
- Optics of stratified systems
- Photonic crystals
- Elements of plasmonics
- Diffractive elements
- Basics of holography
- Plasmonic sensing
- MEMS and MOEMS
- Waveguide theory
- Basics of nonlinear optics
- Fiber optics
- Optical interconnects, switches, and neural nets

Course coordinators

Jolanta Szostak

Type of course

obligatory courses

Mode

Classroom

Prerequisites (description)

Basic knowledge of Maxwell equations, of mathematical analysis, and of programming.

Learning outcomes

Learning the physical basis of operation of major photonic elements, learning the ability to formulate the mathematical and numerical description of the operation of simple optical systems.

Assessment criteria

Aural exam and the results of the exercises.

Bibliography

E. Hecht, Optics, 4th ed. Addisson Wesley2002
B. Saleh, M. Teich, Fundamentals of Photonics, (Wiley, 2007)
II. M. Karpierz, E. Weinert-Rączka, Nieliniowa Optyka Światłowodowa, WNT 2009
III. D. Griffiths, Podstawy elektrodynamiki, PWN 2005
IV. J. Joannopolous, S. Johnson, , J.Winn, R. Meade, Photonic Crystals, Molding the flow of light, 2nd Ed, Princeton Univ. Press, 2008
V. J. Gaj, Elektryczność i magnetyzm, Wyd.UW 2000
VI. Feynmana wykłady z fizyki, t. 2.2 (elektrodynamika), PWN