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Introduction to Photonics
EEN 413

Description
Course Purpose and Objectives

Photonics 441 is a four hour per week course designed to give an understanding of the many facets of photonics.

Learning Outcomes

Detailed knowledge of Photonics.

Prerequisites

Electromagnetism

Course Content

1. Introduction to Photonics and Optical Communication

Overview of photonics and the applications in different areas such as information technology and communications, healthcare, life sciences, optical sensing, lighting, energy and manufacturing. The evolution of light-wave systems will be discussed before the basics of optical communications systems will be introduced.

2. Nature of light and the production of EM radiation for photonics applications

i) Wave Nature of Light

Light waves in homogeneous media. Refractive index. Group velocity and group index. Magnetic field, Irradiance and Poynting vector. Snell's law and total internal reflection. Fresnel's equations. Multiple interference and optical resonators. Temporal and spatial coherence. Diffraction principles. Polarisation. Methods to define the characteristics of light mathematically (Stokes parameters, Jones vectors & matrices) and how to determine these characteristics.

ii) Optical sources and transmitters

Principles of light emission and amplification in semiconductors, light emitting diodes, semiconductor lasers (edge emitting lasers and VCSELs).

Semiconductor science and light emitting diodes (LED). Semiconductor concepts and energy bands. Direct and indirect band-gap semiconductors: E-k diagrams. P-n junction principles and band diagram. LED and materials. Heterojunction high intensity LED and characteristics. Steady state semiconductor rate equation. LED for Optical fibre communications. Single frequency solid state lasers. Quantum well devices. Optical amplifiers.

3. Optical waveguides

The propagation of light in optical waveguides.

Dielectric waveguides and optical fibres. Symmetric planar dielectric slab waveguide. Modal and waveguide dispersion in the planar waveguide. Step index fibre. Numerical aperture. Dispersion in single mode fibres. Bit-rate, dispersion and optical non-linearities, Electrical and optical bandwidth. Graded index optical fibre. Attenuation in optical fibres-light absorption and scattering. Fibre manufacture.

4. Optical detectors and receivers

The detection of light and the demodulation of light including 

photoconductors, photodiodes and receiver systems.

Principle of the p-n junction photodiode. External photocurrent. Absorption coefficient and photodiode materials. Quantum efficiency and responsivity. The pin, avalanche and heterojunction photodiodes. Phototransistors. Photoconductive detectors and photoconductive gain. Noise in photodetectors. Generic system issues: sources of noise and signal-to-noise ratio, limitations on temporal response and effective bandwidth.

5. Imparting information onto EM radiation & communication techniques

i) Basic modulation principles

Polarisation and modulation of light. Light propagation in anisotropic media: birefringence. Birefringent optical devices. Optical activity and circular birefringence. Electro-optic effects. Integrated optical modulators. Acousto-optic modulator. Magneto-optic effects. Non-linear optics and second harmonic generation.

ii) Modulation

Acousto-optic and electro-optic techniques, LED switching, analogue and digital techniques using lasers, AM, FM, phase modulation techniques

6. Applications for light-wave systems

A summary of important concepts of digital communication including base band and broadband digital transmission, bit error rate, bit group error rate and time division multiplexing (TDM) and wavelength division multiplexing (WDM). Trends and new directions in photonic applications

i) Noise and detection

Noise arising from the properties of fibres, transmitters, receivers and amplifiers as well as the determination of the bit error rate.

ii) Optical MUX and DEMUX

The operating principle of multiplexers and demultiplexers. Different optical devices, essential to optical networks, optical amplifiers, polarisation control devices, optical isolators, optical filters and diffraction gratings, modulators and switches.

iii) Optical systems design

Design process for a point-to-point optical links.


Crédits ECTS
6

Langue d'enseignement
English/Greek

Langue d'examen

Langue des supports pédagogiques

Acquis d'apprentissage fondamentaux

Entité de gestion (faculté)