Subject description - AD2B99LES

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AD2B99LES Laboratory of Electronic Systems Extent of teaching:14+6c
Guarantors:  Roles:PO,V Language of
Teachers:  Completion:Z,ZK
Responsible Department:13131 Credits:6 Semester:L


The objective of the subject is to inform students about potential of electronic circuit simulations. The course is based on concrete applications. Themes of the first part of the lectures are put to a test on basic circuits. Specific circuit applications follow with a detailed explanation and a simulation in exercises afterwards. Selected circuits will be checked by laboratory measurements.

Study targets:

The course aims to introduce students to the possibilities of electronic circuit simulation and practical measurement of their parameters in laboratory exercises. Credit is obtained by processing semestral tasks (simulation and measurement). The overall rating is based on the score during the semester and the oral examination.

Course outlines:

1. Analysis of electronic circuits, programs for analysis, types of analyses. Modeling semiconductor devices, criteria for accuracy assessment. Model of semiconductor diode, DC and transient parts of the model, diode noise model with three basic types of noise.
2. Bipolar junction transistor model (fundamental parameters, modified Gummel-Poon model, characterization of quasi-saturation, modeling delay of microwave transistors).
3. MOSFET models (semiempirical model, fundamental features and properties of BSIM and EKV models, method of modeling LDMOS structures).
4. JFET and MESFET/pHEMT models, modeling frequency dispersion of parameters of microwave transistors. Modeling frequency dispersion on transmission lines.
5. Fundamentals of macromodeling. Basic features of methods for solving systems of nonlinear algebraic-differential equations, i.e. determining operating points and transients.
6. Semisymbolic analysis, calculation of poles and zeros. Quasi-linear analysis, design of mixers.
7. Sensitivity analyses in frequency and time domains, using the sensitivity analysis for optimization.
8. Real operational amplifier, parameters, modeling, possibilities of parameter measurements. 9. Selected nonlinear applications with operational amplifier, principles, properties, simulation problems.
10. Feedback structures, possibilities of semisymbolic analysis, usage of mathematical programs.
11. Linear regulators, used circuits, properties.
12. Oscillators, the conditions of oscillation, amplitude control, derivation, simulation capabilities.
13. Power amplifiers, classes, fundamental circuitry, parameter classification and measurement, digital amplifiers.
14. Fundamental circuits with switched capacitors - simulation possibilities by means of classical methods.

Exercises outline:

1. Simulator structure (graphical editor, core simulator, working with netlist, graphical postprocessor).
2. Circuit simulation, types of DC analysis.
3. Circuit simulation, frequency and noise analyses.
4. Circuit simulation, transient and Fourier analysis.
5. Other types of analyses that are specialized to radio engineering.
6. Controlling accuracy and reliability (convergence) by means of algorithm parameters.
7. Simulations with macromodels of integrated circuits, especially of operational amplifiers.
8. Laboratory exercise - measurement of the operational amplifier parameters.
9. Laboratory exercise - measurement of the operational rectifier parameters.
10. Semisymbolic analysis of feedback structures.
11. Laboratory exercise - measurement of the feedback regulator parameters.
12. Transient and spectral analysis of oscillator - calculation of distortion.
13. Laboratory exercise - measurement of digital power amplifier parameters.
14. Basic simulation of periodic switched linear circuits, credits.


1. J. Dostál, Operaional Amplifiers. SNTL Publishers of Technical Literature, Prague 1981. ISBN 0-444-99760-1.
2. J. Dostál, Operační Zesilovače. Praha : BEN - technická literatura, 2005. ISBN 80-7300-049-0.
3. J. Dobeš, V. Žalud: Moderní radiotechnika, BEN - technická literatura, Praha 2006.
4. T.A. Fjedly, T. Ytterdal, M. Shur, Introduction to Device Modeling and Circuit Simulation, John Wiley & Sons, New York 1998.
5. Andrei Vladimirescu, The SPICE Book, Wiley 1993, ISBN 0471609269.
6. Y. Cheng and C. Hu, MOSFET Modeling & BSIM3 Users Guide, Kluwer Academic Publishers, Boston 1999.
7. Adel S. Sedra, Kenneth C. Smith: Microelectronic Circuits, Oxford University Press, 5. vydání, 2003, ISBN 0195142519.


Basic knowledge of electrical and electronic circuits and their analysis.

Subject is included into these academic programs:

Program Branch Role Recommended semester
BKOI1 Computer Systems V 6
BKOI_BO Common courses V 6
BKOI3 Software Systems V 6
BKOI2 Computer and Information Science V 6
BKKME3 Applied Electronics PO 6
BKEEM1 Applied Electrical Engineering V 6
BKEEM_BO Common courses V 6
BKEEM2 Electrical Engineering and Management V 6
BKKYR1 Robotics V 6
BKKYR_BO Common courses V 6
BKKYR3 Systems and Control V 6
BKKYR2 Sensors and Instrumentation V 6
BIS(ECTS)-D Intelligent Systems V 6
BKSTMWM Web and Multimedia V 6
BKSTMSI Software Engineering V 6
BKSTMMI Manager Informatics V 6
BKSTMIS Intelligent Systems V 6
BKSTM_BO Common courses V 6
BSI(ECTS)-D Software Engineering V 6
BWM(ECTS)-D Web and Multimedia V 6
BMI(ECTS)-D Manager Informatics V 6

Page updated 14.6.2019 17:52:56, semester: Z,L/2020-1, L/2018-9, Z,L/2019-20, Send comments about the content to the Administrators of the Academic Programs Proposal and Realization: I. Halaška (K336), J. Novák (K336)