Course description

INTRODUCTION: challenges and trends in Optoelectronics

LIGHT: short revision of models of light, propagation, light and matter, complex refractive index, reflection, refraction, scattering, colour spaces

OPTICAL SOURCES: generation of light, overview of optical sources

– Light emitting diodes (LED): direct semiconductors, spontaneous emission, LED structures, technology, optical and electrical characteristics, examples of driver circuits, organic LED (OLEDs)

– Lasers: operational principle, stimulated emission, main parts of a laser, optical amplification and losses, spectrum and shape of the output beam, applications of lasers

– Laser diodes: structures, PN, DH, DBR, DFB VCSEL LD, applications

PHOTODETECTORS: detection of light in semiconductor, semiconductor photodetectors (pn, pin, heterodiode, avalance, phototransistor), circuits with photodetectors, operational principles and structures of CCD, CMOS and a-Si:H detector arrays

DISPLAYS: structure and operation of LCD, LED, plasma and OLED displays, 3D displays

OPTICAL FIBERS: guiding light in a fiber, single and multimode fibers, attenuation, dispersion, non-linear effects

PHOTOVOLTAICS: trends, solar spectrum, radiation and irradiation, how a solar cell work, technologies of solar cells and photovoltaics modules, photovoltaic systems, steps design of a solar power plant, examples

6 tasks are conducted from the above mentioned topics within the practice work of the course. One of them is elective and is carried out in the research Laboratory of Photovoltaics and Optoelectronics.

Course is carried out on study programme

Elektrotehnika 1. stopnja

Objectives and competences

The objectives of the course are to familiarize students with the state-of-the-art knowledge on optoelectronics and photonics with emphasis on contemporary optoelectronic devices and their structures and to understand their operational principles. Issues important for electrical engineers will be pointed out such as connection of optoelectronic components with other electronic components and circuits. Related to photovoltaics students will learn about the importance of renewable energy sources and the photovoltaics among them, they will learn and think about different technical solutions of PV systems.

Learning and teaching methods

The lectures provide a theoretical background on particular subjects together with presentation of selected practical examples. Handouts of slides are available as well as additional study material. Practical work is devoted to hands-on – working with optoelectronic components.

Intended learning outcomes

After successful completion of the course, students should be able to:

  • explain basic operational principles of optoelectronic devices
  • calculate selected optical and electrical characteristics of devices
  • measure basic characteristics of devices
  • select an appropriate optoelectronic component for certain application
  • design a simple electronic circuit for connection of an optoelectronic device
  • carry out basic steps in design of a photovoltaic array for a simple photovoltaic power plant

Reference nosilca

  1. KRČ, Janez, TOPIČ, Marko. Optical modeling and simulation of thin-film photovoltaic devices. New York: CRC Press, 2013.
  2. KRČ, Janez, SEVER, Martin, TOPIČ, Marko. The two approaches of surface-texture optimization in thin-film silicon solar cells. IEEE journal of photovoltaics, ISSN 2156-3381, Oct. 2013, vol. 3, no. 4, str. 1156-116
  3. KRČ, Janez, LIPOVŠEK, Benjamin, TOPIČ, Marko. Design for high out-coupling efficiency of white OLED using CROWM – a combined geometric/wave optics model. V: Optical Nanostructures and Advanced Materials for Photovoltaics (2013). [S. l.]: The Optical Society, cop. 2014.
  4. KRČ, Janez, SEVER, Martin, ČAMPA, Andrej, STELTENPOOL, Mark, MOULIN, Etienne, ERVEN, Rob van, HAUG, Franz-Josef, BALLIF, Christophe, TOPIČ, Marko. Design of advanced surface-textures for thin-film silicon micromorph solar cells. V: Photovoltaic Science and Engineering Conference, October 28 – November 1, 2013, Taipei, Taiwan. PVCES-23 : technical digest. [S. l.: s. n.], 2013, str. 1-
  5. KRČ, Janez, LIPOVŠEK, Benjamin, TOPIČ, Marko. Light management in thin-film solar cell. V: LÓPEZ, Ana Belén Cristóbal (ur.), VEGA, Antonio Martí (ur.), LÓPEZ, Antonio Luque (ur.). Next generation of photovoltaics : new concepts, (Springer series in optical sciences, ISSN 0342-4111, 165). Berlin; Heidelberg: Springer, cop. 2012, str. 95-129.

Study materials

1. J. Krč, Prosojnice predavanj, dostopne so na e-FE/ / Slides of lectures, available at e-FE

2. B. Lipovšek, Navodila za laboratorijske vaje pri predmetu Optoelektronika (založba UL FE) in zbirka rešenih primerov na e-fe / Instructions for practical work – Optoelectronics (bookstore UL FEE) and Calculation examples with results (e-fe)

3. S. O. Kasap, Optoelectronics and Photonics – principles and practices, 2nd Ed. Pearson Education, 2013

4. A. Luque, S. Hegedus, Handbook of photovoltaic science and engineering, Wiley, 2011.

5. B. E. A. Saleh, Fundamentals of photonics, Wiley, 2007.

Bodi na tekočem

Univerza v Ljubljani, Fakulteta za elektrotehniko, Tržaška cesta 25, 1000 Ljubljana

E:  dekanat@fe.uni-lj.si T:  01 4768 411