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19E062OFE - Fundamentals of Physical Electronics

Course specification
Course title Fundamentals of Physical Electronics
Acronym 19E062OFE
Study programme Electrical Engineering and Computing
Module Electronics and Digital Systems, Physical Electronics, Physical Electronics - Biomedical and Environmental Engineering, Physical Electronics - Biomedical and Nuclear Engineering, Signals and Systems
Type of study bachelor academic studies
Lecturer (for classes)
Lecturer/Associate (for practice)
Lecturer/Associate (for OTC)
    ESPB 6.0 Status elective
    Condition
    The goal Introducing students to the fundamental theory of the electronic band structure of semiconductors. From this foundation, students build knowledge in the field of semiconductor electronic and optoelectronic devices, including diodes, transistors, lasers, LEDs, photodetectors, and solar cells.
    The outcome Mastering the principles of operation of modern semiconductor electronic and optoelectronic devices, providing a foundation for understanding advanced courses such as analog and digital electronics, optical communications and computing, quantum mechanics, statistical physics, quantum electronics, micro- and nanoelectronics, and spintronics.
    Contents
    URL to the subject page http://nobel.etf.bg.ac.rs/studiranje/kursevi/of2ofe
    Contents of lectures Kronig-Penney model. Intrinsic and doped semiconductors, carrier density, transport in semiconductors, inhomogeneous semiconductor. PN junction, transient regime in diodes. Metal-semiconductor junction, MOS structures, heterostructures. Semiconductor optoelectronic devices, lasers, LEDs, photodetectors, solar cells. J-FETs, MOSFETs and bipolar transistors. CMOS image sensor.
    Contents of exercises Auditory exercises: Numerical examples based on lectures. Homework assignments.
    Literature
    1. Dejan Gvozdić: "Fundamentals of Physical Electronics", Academic Mind, 2017.
    2. Jasna Crnjanski, Dejan Gvozdić, "Problems with solutions in Fundamentals of Physical Electronics," Academic Mind, 2021.
    3. Beng G. Streetman and Sanjay Banerjee: Solid State Electronic Devices , Prentice Hall, 2000. (Original title)
    4. D. Neamen: Semiconductor Physics and Devices - basic principles, Mc Graw Hill, 2011. (Original title)
    5. I.A.S.Sedra, K.C. Smith: Microelectronic Circuits, Oxford University Press, 1998. (Original title)
    Number of hours per week during the semester/trimester/year
    Lectures Exercises OTC Study and Research Other classes
    3 2
    Methods of teaching Lectures and auditory exercises.
    Knowledge score (maximum points 100)
    Pre obligations Points Final exam Points
    Activites during lectures Test paper 40
    Practical lessons 20 Oral examination
    Projects
    Colloquia 40
    Seminars