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13E063KE - Quantum Electronics

Course specification
Course title Quantum Electronics
Acronym 13E063KE
Study programme Electrical Engineering and Computing
Module Physical Electronics - Nanoelectronics, Optoelectronics, Laser Technology
Type of study bachelor academic studies
Lecturer (for classes)
Lecturer/Associate (for practice)
Lecturer/Associate (for OTC)
    ESPB 6.0 Status elective
    Condition none
    The goal The course introduces students into fundamental principles of quantum mechanical interaction of photon and atomic systems, which can be extended to general knowledge in the interaction of electromagnetic field with material, concepts of optical gain, spontaneous and stimulated emission, their relation to susceptibility and light propagation in anisotropic media.
    The outcome Mastering theoretical basis and adopting methods used in the further study of active and passive optoelectronic and electro-optical components and subsystems, which are used in optical communications, fiber-optic sensors, laser technology, materials science, biophotonics, nanophotonics and photonics in general.
    Contents
    URL to the subject page http://nobel.etf.bg.edu.rs/studiranje/kursevi/of3ke/?p=informacije
    Contents of lectures Time-dependent perturbation theory. Interaction of electromagnetic (EM) radiation and atomic systems. The Kramers-Kronig relations. EM fields and their quantization. Spontaneous and induced transitions. Homogeneous and inhomogeneous broadening. Absorption and gain. Optical resonators. Laser oscillation. Transverse modes and Gauss beams. EM field in anisotropic crystals. Modulation of EM waves.
    Contents of exercises Auditory exercises: Numerical examples based on lectures.
    Literature
    1. Dejan Gvozdić: "Quantum Electronics", http://nobel.etf.bg.edu.rs/studiranje/kursevi/of3ke/?p=materijali
    2. Arsoski Vladimir: "Solved problems in Quantum Electronics", http://nobel.etf.bg.edu.rs/studiranje/kursevi/of3ke/?p=materijali
    3. A. Yariv, "Quantum Electronics," John Wiley and Sons, 1989.
    4. A. Yariv, "Optical Electronics in Modern Communications," Oxford University Press, 2006.
    5. W. Boyd, "Nonlinear Optics," Academic press, 2003
    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 0 Test paper 30
    Practical lessons 0 Oral examination 0
    Projects
    Colloquia 70
    Seminars 0