13E063OE - Optoelectronics

Course specification
Course title		Optoelectronics
Acronym		13E063OE
Study programme		Electrical Engineering and Computing
Module		Electronics, Electronics and Digital Systems, Physical Electronics - Biomedical and Nuclear Engineering, Physical Electronics - Nanoelectronics and Photonics, Physical Electronics - Nanoelectronics, Optoelectronics, Laser Technology
Type of study		bachelor academic studies
Lecturer (for classes)		professor PhD Petar Matavulj
Lecturer/Associate (for practice)		professor PhD Jovana Gojanović
Lecturer/Associate (for OTC)		professor PhD Jovana Gojanović asst. MA Milena Mićić, electrical and computer engineer
ESPB		6.0	Status	elective
Condition		no
The goal		1) Recognizing physical processes which are consequence of light propagation and light - matter interaction and explanation of possibilities for their application. 2) Understanding how work basic optoelectronic devices. 3) Demonstration of basic optoelectronic processes via experiment and teaching and training students how to correctly use optoelectronic components and tools.
The outcome		It is expected that every student: 1) learns about important role and application of optoelectronics in current and future development of society, 2) gains knowledge about basic optical processes and optoelectronic devices and 3) overcome all difficulties when practically uses basic optoelectronics devices and tools and should be ready to use them alone.
Contents
Contents of lectures		Optoelectronics - words meaning and applications. Ray/geometrical optics. Abberations. Optical fibers. Superposition of waves. Wave/physical optics. Dispersion, polarization, interference and diffraction. Fourier optics. Nonlinear optics - introduction. Light sources: discret - laser, narrowband spectral sources, wideband spectral sources. Detectors. Polymer optoelectronics.
Contents of exercises		Laboratory tutorial: 1. Characterization of Gaussian light beam - Light beam optics (Ray optics). 2. Determining of diffraction pinhole and wire radius - Wave optics, CCD. 3. Finding Verde constant for known crystal - Polarization. 4. Determining of He - Ne laser resonator length - Lasers. 5. Optimization of optical receiver input stage - Detectors.
Literature
Optoelectronics, P. Matavulj, lecture notes, Faculty of Electrical Engineering, Belgrade, 2007. Problems in Optoelectronics - light propagation, J. Gojanović, P. Matavulj, Academic Mind, 2020, ISBN 978-86-7466-848-1 Optics, E. Hecht, 4ed, Addison Wesley, 2002. ISBN 0-321-18878-0. (Original title) Electro-Optics Handbook, R. Waynant, M. Ediger, McGraw-Hill Inc., 2000. ISBN 0-07-068716-1. (Original title) Semiconducting Polymers, G.Hadziioannou, P.F.van Hutten, Wiley-Vch, 1999. ISBN 3-527-29507-0. (Original title)
Number of hours per week during the semester/trimester/year
Lectures	Exercises	OTC	Study and Research	Other classes
3	1	1
Methods of teaching		Lectures, auditory exercises, lab tutorial and homework(s).
Knowledge score (maximum points 100)
Pre obligations		Points	Final exam	Points
Activites during lectures		0	Test paper	35
Practical lessons		30	Oral examination	0
Projects
Colloquia		35
Seminars		0