Course Identification

Title:

Free space and guided wave optics

Code:

20241242

Lecturers and Teaching Assistants

Lecturers:

Prof. Ulf Leonhardt

TA's:

Jonathan Kogman

Course Schedule and Location

Year:

2024

Semester:

Second Semester

When / Where:

Sunday, 09:15 - 11:00, FGS, Rm 4
Wednesday, 09:15 - 11:00, FGS, Rm 4

First Lecture:

07/04/2024

End date:

09/07/2024

Field of Study, Course Type and Credit Points

Physical Sciences: Lecture; 4.00 points
Chemical Sciences: 4.00 points

Comments

classical mechanics, electromagnetism, quantum mechanics
The course will take place at Drori auditorium

Prerequisites

classical mechanics, electromagnetism, quantum mechanics

Restrictions

Participants:

20

Language of Instruction

English

Attendance and participation

Expected and Recommended

Grade Type

Numerical (out of 100)

Grade Breakdown (in %)

Interim:

50%

Final:

50%

Evaluation Type

Take-home exam

Scheduled date 1

Date / due date

N/A

Location

N/A

Time

-

Remarks

N/A

Estimated Weekly Independent Workload (in hours)

6

Syllabus

1. Geometrical optics: Fermat's principle, refraction, transformation optics, Hamilton's equations, ABCD matrices, simple optical instruments.

2. Waves: interference and reflection. Fresnel coefficients, transfer matrix, scattering matrix, Bragg reflector, Fabry-Perot interferometer.

3. Polarisation: plane electromagnetic waves, Jones vector and Poincare sphere, reflection and refraction at interface, Brewster angle, birefringence.

4. Fourier optics: scalar diffraction, optical Schroedinger equation, Fresnel and Fraunhoffer regime, Wigner function, Gaussian beams, nondiffracting beams, accelerating beams.

5. Applications of Fourier optics: diffraction theory of the lens, resolution limit, microscopy. spatial and spectral filtering, gratings.

7. Wave guides: slab waveguide, effective index profile, Silicon photonics, ring resonators, GRIN devices, transformation optics on chip.

8. Fibers: analogy to waveguides, dispersion, single-mode/multi-mode fibers, photonic-crystal fibers.

Learning Outcomes

Upon successful completion of this course students should be able to:

Demonstrate good proficiency in topics in linear and Fourier optics.

Continue with further advanced studies of various topics in atomic, molecular and optical physics.

Design and understand the design of basic optical instruments.

Reading List

Goodman "Introdution to Fourier Optics"

Born and Wolf "Principles of Optics"

Website

N/A