Gurantor department | Department of Theoretical Electrical Engineering | Credits | 6 |

Subject guarantor | doc. Dr. Ing. Josef Punčochář | Subject version guarantor | doc. Dr. Ing. Josef Punčochář |

Study level | undergraduate or graduate | Requirement | Compulsory |

Year | 1 | Semester | winter |

Study language | Czech | ||

Year of introduction | 2006/2007 | Year of cancellation | 2007/2008 |

Intended for the faculties | FEI | Intended for study types | Follow-up Master |

Instruction secured by | |||
---|---|---|---|

Login | Name | Tuitor | Teacher giving lectures |

PUN10 | doc. Dr. Ing. Josef Punčochář |

Extent of instruction for forms of study | ||
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Form of study | Way of compl. | Extent |

Full-time | Credit and Examination | 3+3 |

Part-time | Credit and Examination | 0+20 |

After completing this course, the student should be able to
analyze and construct electronic circuits (amplifiers, filters, oscillators,convertors, ...) with real active circuit elements:
operational amplifier;
transconductance amplifier;
transimpedance amplifier;
current conveyor;
analog multiplier

Admittance models of modern amplifier structures; feedback; nodal analysis in
active - network theory; linear circuit analysis - frequency and time domain
(amplifiers, filters);harmonic oscillators and square wave generators; analog
multipliers; modulation and demodulation; signal sampling; A/D and D/A
convertor principles; degradation of electronic components.

Punčochář, J.: Lineární obvody s elektronickými prvky. Skriptum, VŠB-TU Ostrava 2002
Mohylová, J.: Lineární obvody s elektronickými prvky -Sbírka příkladů, VŠB-TU Ostrava 2002
Punčochář, J.: Modern integrated electronic devices in linear circuit theory. XXIII. IC-SPETO-2000,p.p. 279-282
Punčochář, J.: Admittance models of modern linear amplifying structures. Transactions of the VŠB - Technical University of Ostrava, VI, 1, 2003, p.p. 151-161
Mohylová, J.: Analysis of linear circuits by means of MATLAB.Transactions of the VŠB - Technical University of Ostrava, VI, 1, 2003, p.p. 114-125

Huelsman,L. P.: Basic circuit theory. Prentice - Hall Editions, Third edition, 1991
Mikulec, M.-Havlíček, V.: Basic circuit theory (I, II), ČVUT - Praha
Hejda, Z.-Punčochář, J.: The 1. order high-pass filter.Admittance models of modern linear amplifying structures. Transactions of the VŠB - Technical University of Ostrava, VI, 1, 2003, p.p. 50-55
Kolář, J.-Punčochář, J.: Band stop filtr with real operational amplifier.Transactions of the VŠB - Technical University of Ostrava, VI, 1, 2003, p.p. 92-100
Mohylová, J.: Influence of inverter vector error on common mode signal transmission of differential amplifier. http://www.elektrorevue.cz/index.php.en

Conditions for credit:
Student must work out three tests. Student can receive up to 3 points for each of tests. Maximum number of points student can gain through tests is 3 * 3 = 9 points.
Student can gain up to 12 points from the laboratory exercises (6 * 2 = 12 - 2 points each problem).
Student can gain up to 9 points from the computer exercises (3 * 3 = 9 - 3 points each problem).
Student can gain up to 14 points from the project.
To pass the excercises part of course student has to gain at least 26 points.
Student can gain up to 56 points from the final exam (circuit work - 32 points, oral part - 24 points).
To pass the course student has to gain at least 51 points.

Subject has no prerequisities.

Subject has no co-requisities.

Lectures:
History of electronics; basic models and theorems (immittance functions, Thevenin and Norton´s theorems, equivalent input and output impedances); quiescent point - as common problem; linearization.
Quiescent point of basic active tripole (BJT, FET, triode); their admittance models.
Modern amplifier structures (VFA, CFA, OTA, Northon´s amplifier, conveyors) and their admittance models.
Feedback theory, Nyquist stability criterion - application.
Generalized nodal voltage analysis (GNVA), admittance model of linear electronic circuit (related to feedback theory, stability - determination from the admittance model).
Analysis of amplifier and oscillator structures by means of GNVA.
Analysis of 2. order filters, principles of cascading - higher order filters - an example.
Rectifiers, voltage and current sources, logarithmic amplifier, analog multiplier.
Modulation, demodulation, signal sampling.
A/D and D/A converter principles; application of D/A convertor and analog multiplier for filters frequency controlling.
Compression amplifier, stabilization of oscillator amplitude.
Amplifiers and filters in the time domain, influence of an op amp slew rate and recovery time.
Relaxation structures (nonharmonic signals - square wave, triangular wave, saw-tooth) - triangle-to-sinusoid conversion.
Degradation of electronic elements with temperature, dissipated power (causes of degradation) - reduction of influence (abduction of heat - heat sink); structural and theoretical connection between analog and digital technics.
Exercises:
Quiescent point of basic active tripoles (BJT, FET, triode); definition of project.
Analysis of input differential stage, middle stage and output stage (follower, rail to rail) of OPA.
Admittance models of inverting and or noninverting structures (ideally frequency nondependent).
Admitance models of 2. order RC filters
Admitance models of RC oscillators.
Amplifiers - time domain; astable multivibrator with OPA.
Reports on projects.
Laboratories:
Verification of quiescent point definitions of basic tripoles.
Measuring of amplifier frequency responses.
Measuring of 2. order filter frequency responses.
Measuring of amplifiers in the time domain.
Measuring of 2. order filters in the time domain.
Measuring of OPA astable multivibrator properties; influence of slew rate; warming with frequency.
Reserve.
Computer labs:
Introduction to the MATLAB - connection with admittance models of electronic elements.
Amplifier frequency responses (ideally frequency nondependent)- influence of real OPA properties.
Frequency dependent structures (filters)- influence of real OPA properties in the frequency domain.
Amplifier time responses (ideally frequency nondependent)- influence of real OPA properties.
Frequency dependent structures (filters)- influence of real OPA properties in the time domain.
Elaboration of project.
Elaboration of project.

Task name | Type of task | Max. number of points
(act. for subtasks) | Min. number of points |
---|---|---|---|

Exercises evaluation and Examination | Credit and Examination | 100 (100) | 51 |

Exercises evaluation | Credit | 44 (44) | 0 |

Laboratory work | Laboratory work | 12 | 0 |

Project | Project | 23 | 0 |

Written exam | Written test | 9 | 0 |

Examination | Examination | 56 (56) | 0 |

Written examination | Written examination | 32 | 0 |

Oral | Oral examination | 24 | 0 |

Show history

Academic year | Programme | Field of study | Spec. | Zaměření | Form | Study language | Tut. centre | Year | W | S | Type of duty | |
---|---|---|---|---|---|---|---|---|---|---|---|---|

2007/2008 | (N2649) Electrical Engineering | (2601T004) Measurement and Control Engineering | P | Czech | Ostrava | 1 | Choice-compulsory | study plan | ||||

2007/2008 | (N2649) Electrical Engineering | (2601T004) Measurement and Control Engineering | K | Czech | Ostrava | 1 | Choice-compulsory | study plan | ||||

2007/2008 | (N2649) Electrical Engineering | (2612T015) Electronics | P | Czech | Ostrava | 1 | Compulsory | study plan | ||||

2007/2008 | (N2649) Electrical Engineering | (2612T015) Electronics | K | Czech | Ostrava | 1 | Compulsory | study plan | ||||

2006/2007 | (N2649) Electrical Engineering | (2601T004) Measurement and Control Engineering | P | Czech | Ostrava | 1 | Choice-compulsory | study plan | ||||

2006/2007 | (N2649) Electrical Engineering | (2612T015) Electronics | P | Czech | Ostrava | 1 | Compulsory | study plan | ||||

2006/2007 | (N2649) Electrical Engineering | (2612T015) Electronics | K | Czech | Ostrava | 1 | Compulsory | study plan |

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