PAUL C.R., WHITES K.W., NASAR S. A., Introduction to Electromagnetic Fields, McGraw-Hill, New York, 1998
SZE, S. M.: Modern Semiconductor Device Physics, Willey, 2000
Terminated in academic year 2020/2021
Nanoelectronics
| Type of study | Follow-up Master |
|---|---|
| Language of instruction | Czech |
| Code | 440-8740/01 |
| Abbreviation | NE |
| Course title | Nanoelectronics |
| Credits | 5 |
| Coordinating department | Department of Telecommunications |
| Course coordinator | Dr. Ing. Libor Gajdošík |
Subject syllabus
Lectures:
1. Maxwell's equations in vacuum.
2. Maxwell's equations in material.
3. Basic laws in electrical circuit.
4. Limits of validity of Ohm's and Kirchhoff''s laws.
5. Electrical and mechanical analogies.
6. Limits of electrical and mechanical analogies.
7. Solution of mechanical systems as electrical circuits.
8. Using of nanomaterials in electronics.
9. Using of nanomaterials for electromechanical devices.
10. Possible realization of logical circuits as nanosystems.
11. Possible realisations of nano-transistors.and nano-diodes
12. Possibilities of nanoelectronics in data transfer.
13. Possible realisations of nano-electrical and mechanical systems.
14. Possible realisations of nano-electroacustic systems
Exercises:
1. Calculation of forces in electrical and magnetical field.
2. Flat capacitor, linear inductor.
3. Calculation of voltages and currents in circuits.
4. Solution of the circuit with lumped elements and distributed elements.
5. Solution of mechanical oscillator.
6. Solution of microphone and loudspeaker.
7. Test1
8. Solution of mechanical filter.
9. Solution of electromechanical resonator.
10. Solution of Helmhotz resonator.
11. Design of logical circuit with discrete elements.
12. Analysis of action of bipolar transistor and diode.
13. Test2.
14. Credit.
1. Maxwell's equations in vacuum.
2. Maxwell's equations in material.
3. Basic laws in electrical circuit.
4. Limits of validity of Ohm's and Kirchhoff''s laws.
5. Electrical and mechanical analogies.
6. Limits of electrical and mechanical analogies.
7. Solution of mechanical systems as electrical circuits.
8. Using of nanomaterials in electronics.
9. Using of nanomaterials for electromechanical devices.
10. Possible realization of logical circuits as nanosystems.
11. Possible realisations of nano-transistors.and nano-diodes
12. Possibilities of nanoelectronics in data transfer.
13. Possible realisations of nano-electrical and mechanical systems.
14. Possible realisations of nano-electroacustic systems
Exercises:
1. Calculation of forces in electrical and magnetical field.
2. Flat capacitor, linear inductor.
3. Calculation of voltages and currents in circuits.
4. Solution of the circuit with lumped elements and distributed elements.
5. Solution of mechanical oscillator.
6. Solution of microphone and loudspeaker.
7. Test1
8. Solution of mechanical filter.
9. Solution of electromechanical resonator.
10. Solution of Helmhotz resonator.
11. Design of logical circuit with discrete elements.
12. Analysis of action of bipolar transistor and diode.
13. Test2.
14. Credit.
Literature
Advised literature
HAYTT WH, Engineering Electromagnetics, McGraw-Hill, New York, 1989
COLLIN R. E., Antennas and Radiowave Propagation, McGraw-Hill, New York 1985
SZE, S. M., CHANG, C. Y.: ULSI Device, Willey, 2000
COLLIN R. E., Antennas and Radiowave Propagation, McGraw-Hill, New York 1985
SZE, S. M., CHANG, C. Y.: ULSI Device, Willey, 2000