ID: 1324
Course type: theoretical and methodological
Course coordinator: Lukić M. Petar
Lecturers: Lukić M. Petar
Contact: Lukić M. Petar
Level of studies: M.Sc. (graduate) Academic Studies – Mechanical Engineering
ECTS: 6
Final exam type: written+oral
Department: Department of Physics and Electrical Engineering
Understanding the fundamental laws of the Electronics and the attainment of competencies for the further development of the academic knowledge and skills in scientific, professional and applied engineering areas and mechanical engineering that rely on Electronics. Understanding the fundamental components and circuits that are used in Electronics and methods for their analysis, simulation and design.
Staying in the program, students acquire the ability to carry out scientific and technical activities. Mastered the methods of analysis, measurements and design, predictions and solutions consideration of consequences. Acquire an understanding of research and practical methods in the field of electronics that would adequately be able to apply in resolving concrete problems in mechanical engineering.
Place and Role of Electronics; object of study; a brief history; electronic components and electronic circuits - some basic share; signals in electronic circuits. Fundamentals of semiconductor physics: structure of crystals, pure and doped semiconductors,electrical properties, transport processes; p-n junction: directly and inversely polarized. Semiconductor diodes: structure, role and working principle, static and approximate static characteristics, models for small and large signals, temperature effects, polarization, specific types of diodes. Bipolar transistors: structure, roles and working principle, static characteristics, polarization, models for large and small signals, Darlington configuration. Unipolar transistors - FETs, JFET and MOSFET: structure and functioning, role and working principle, static characteristics, polarization, models for large and small signals, SiC and heterostructure based transistors. Basic circuits with diodes: half-wave and full-wave rectifiers, diode clipping and clamping circuits. Basic amplifier configurations, types and specifications, common emitter, common base and common collector amplifiers, operation analysis. Current sources: current mirror, Wilson and Widlar current source. Two-stage and multi-stage amplifiers, the designe principles and operation analysis. Negative feedback: concept, role and types; amplifier with negative feedback amplification and its impact on the characteristics of amplifiers, design principles. Circuits with operational amplifier: operational, differential, inverting, non-inverting amplifier, differentiator, integrator, voltage to current and current to voltage converters, precision rectifiers. Complex circuits - design principles. Linear oscillators roles and types, operation principles, the condition of oscillation,Wien bridge oscillator, Hartley and Colpitts oscillator.
For auditory exercises are being selected numerical examples that follow the curriculum of lectures. Special attention is paid to the analysis of the work of individual electronic circuits, the roles of the individual components in circuits, reviewing of electronic circuits as functional units, but also recognizing the individual characteristic assemblies inside the circuit. The starting point is the easiest circuits, and then tends that students independently, combining smaller units, designed more complex circuits. There is a possibility of laboratory exercises: basic applications of diodes (rectifiers, limiters);common emitter amplifier (adjusting setpoints and recording frequency characteristics); selected circuits with operational amplifiers.
Defined by study program curriculum.
1. Petar M. Lukić: "Fundamentals of Analog Electronics", Faculty of Mechnaical Engineering, University of Belgrade, Belgrade, 2015, ISBN 978-86-7083-855-0 2. Jacob Millman, Arvin Grabel:"Microelectronics", Second Edition, McGraw-Hill Book Company, 1987. 3. Rifat M. Ramović, Rajko M. šašić: "Analysis and modeling of Small Dimensiones Unipolar Transistors", DINEX, Belgrade, 1999. 4. Dejan B. Živković, Miodrag V. Popović: "Impulse and Digital Electronics", Faculty of Electrical Engineering, Nauka, Belgrade, 1992. 5. Slavoljub Marjanović: "Electronics - Discrete and Integrated Analog Circuits", 5th Edition, Faculty of Electrical Engineering, Nauka, Belgrade, 1992. 6. Spasoje Tešić, Dragan Vasiljević: "Fundamentals of Electronics", Građevinska knjiga, Belgrade, 2009., ISBN 978-86-395-0572-1 7. A. Sedra, K. C. Smith: "Microelectronic circuits", 6th Edition, Oxford University Press, NY, 2011, ISBN 978-019-973851-9 8. Handouts
Total assigned hours: 75
New material: 20
Elaboration and examples (recapitulation): 10
Auditory exercises: 20
Laboratory exercises: 8
Calculation tasks: 0
Seminar paper: 2
Project: 0
Consultations: 0
Discussion/workshop: 0
Research study work: 0
Review and grading of calculation tasks: 0
Review and grading of lab reports: 0
Review and grading of seminar papers: 0
Review and grading of the project: 0
Test: 9
Test: 3
Final exam: 3
Activity during lectures: 5
Test/test: 30
Laboratory practice: 0
Calculation tasks: 0
Seminar paper: 0
Project: 0
Final exam: 65
Requirement for taking the exam (required number of points): 30
Petar M. Lukić: "Fundamentals of Analog Electronics", Faculty of Mechnaical Engineering, BU, Belgrade, 2015, ISBN 978-86-7083-855-0; Jacob Millman, Arvin Grabel:"Microelectronics", Second Edition, McGraw-Hill Book Company, 1987.; Spasoje Tešić, Dragan Vasiljević: "Fundamentals of Electronics", Građevinska knjiga, Belgrade, 2009., ISBN 978-86-395-0572-1; Rifat M. Ramović, Rajko M. šašić: "Analysis and modeling of Small Dimensiones Unipolar Transistors", DINEX, Belgrade, 1999.; A. Sedra, K. C. Smith: "Microelectronic circuits", 6th Edition, Oxford University Press, NY, 2011, ISBN 978-019-973851-9