Servizi per la didattica

PORTALE DELLA DIDATTICA

03LTJNX, 03LTJOD

A.A. 2018/19

Course Language

English

Course degree

1st degree and Bachelor-level of the Bologna process in Electronic Engineering - Torino

1st degree and Bachelor-level of the Bologna process in Physical Engineering - Torino

Borrow

02LTJLP

Course structure

Teaching | Hours |
---|---|

Lezioni | 62 |

Esercitazioni in laboratorio | 18 |

Teachers

Teacher | Status | SSD | h.Les | h.Ex | h.Lab | h.Tut | Years teaching |
---|---|---|---|---|---|---|---|

Ortolano Massimo | Ricercatore | ING-INF/07 | 62 | 0 | 24 | 0 | 4 |

Teaching assistant

Context

SSD | CFU | Activities | Area context |
---|---|---|---|

ING-INF/07 | 8 | B - Caratterizzanti | Ingegneria elettronica |

2018/19

This course has two main objectives. The first is to present a sound theory of uncertainty, according to current accepted international standards and practices, introducing also several advanced tools. The second is to introduce a number of fundamental instruments that are part of a typical electronic laboratory, describing their principle of operation, important specifications, sources of uncertainty and applications.

This course has two main objectives. The first is to present a sound theory of uncertainty, according to current accepted international standards and practices, introducing also several advanced tools. The second is to introduce a number of fundamental instruments that are part of a typical electronic laboratory, describing their principle of operation, important specifications, sources of uncertainty and applications.

Knowledge of uncertainty evaluation techniques, and ability to apply in them in basic measurement situations.
Knowledge of the principle of operation of the most common laboratory instruments, and knowledge of the trade-offs required in an instrument design.
Ability to employ the studied laboratory instrumentation in common electronic measurements.

Knowledge of uncertainty evaluation techniques, and ability to apply in them in basic measurement situations.
Knowledge of the principle of operation of the most common laboratory instruments, and knowledge of the trade-offs required in an instrument design.
Ability to employ the studied laboratory instrumentation in common electronic measurements.

Mathematics: Analysis, basics of theory of probability and stochastic processes.
Electronics: Circuit theory, basic operational amplifier circuits.
Electronic measurements: Usage of multimeters and oscilloscopes.

Mathematics: Analysis, basics of theory of probability and stochastic processes.
Electronics: Circuit theory, basic operational amplifier circuits.
Electronic measurements: Usage of multimeters and oscilloscopes.

Uncertainty, a probabilistic approach: Introduction to the probabilistic approach, type B evaluation of the uncertainty, type A evaluation of uncertainty, propagation of uncertainty; 2 labs on the evaluation of the uncertainty (1.5 ECTS: 0.6 ECTS lectures, 0.3 ECTS exercises, 0.6 ECTS lab).
Frequency synthesis and waveform generation: Properties of signal sources, oscillators, direct analogue synthesizers, indirect analogue synthesizers (phase-lock loops), direct digital synthesizers; 2 labs on PLLs and frequency counters (1.5 ECTS: 0.6 ECTS lectures, 0.3 ECTS exercises, 0.6 ECTS lab).
Basic frequency counters: Time interval counter, frequency counter, period counter, reciprocal counter. High frequency counters: Prescaler, heterodyne converter, transfer oscillator (0.9 ECTS: 0.75 ECTS lectures, 0.15 ECTS exercises) .
Spectrum analysers: Bank-of-filter analyser, swept-spectrum analyser, FFT analyser, hybrid analysers; 3 labs on spectrum analyzers (1.5 ECTS: 0.6 ECTS lectures, 0.9 ECTS labs).
Digital multimeters: block diagram, integrating analog-to-digital converters (dual-slope and multi-slope) , resistance measurements, RMS-to-DC converters (thermal and analogue) (1.5 ECTS: 1.2 ECTS lectures, 0.3 ECTS exercises).
Logic analyzers: principle and modes of operation; lab on logic analyzers (0.6 ECTS: 0.3 ECTS lectures, 0.3 ECTS lab).
Introduction to reliability: terms and definitions, models of failure rates, reliability analysis for electronic components (0.5 ECTS).

Uncertainty, a probabilistic approach: Introduction to the probabilistic approach, type B evaluation of the uncertainty, type A evaluation of uncertainty, propagation of uncertainty; 2 labs on the evaluation of the uncertainty (1.5 ECTS: 0.6 ECTS lectures, 0.3 ECTS exercises, 0.6 ECTS lab).
Frequency synthesis and waveform generation: Properties of signal sources, oscillators, direct analogue synthesizers, indirect analogue synthesizers (phase-lock loops), direct digital synthesizers; 2 labs on PLLs and frequency counters (1.5 ECTS: 0.6 ECTS lectures, 0.3 ECTS exercises, 0.6 ECTS lab).
Basic frequency counters: Time interval counter, frequency counter, period counter, reciprocal counter. High frequency counters: Prescaler, heterodyne converter, transfer oscillator (0.9 ECTS: 0.75 ECTS lectures, 0.15 ECTS exercises) .
Spectrum analysers: Bank-of-filter analyser, swept-spectrum analyser, FFT analyser, hybrid analysers; 3 labs on spectrum analyzers (1.5 ECTS: 0.6 ECTS lectures, 0.9 ECTS labs).
Digital multimeters: block diagram, integrating analog-to-digital converters (dual-slope and multi-slope) , resistance measurements, RMS-to-DC converters (thermal and analogue) (1.5 ECTS: 1.2 ECTS lectures, 0.3 ECTS exercises).
Logic analyzers: principle and modes of operation; lab on logic analyzers (0.6 ECTS: 0.3 ECTS lectures, 0.3 ECTS lab).
Introduction to reliability: terms and definitions, models of failure rates, reliability analysis for electronic components (0.5 ECTS).

In addition to lectures, the course consists of in-class exercise sessions, laboratory sessions and homework assignments.
Exercise sessions are aimed at analysing practical measurement situations involving different type of instruments.
Laboratory sessions are aimed at developing experimental skills, practicing with the laboratory instrumentation described in the lectures and introduce a number of applications. The laboratory sessions focus on the following topics: uncertainty, frequency measurements, frequency synthesis with phase-lock loops, spectrum analysers.
Homework assignments presenting exam-like problems are aimed at encouraging a gradual study of the subject (optional, with approximate biweekly frequency).

In addition to lectures, the course consists of in-class exercise sessions, laboratory sessions and homework assignments.
Exercise sessions are aimed at analysing practical measurement situations involving different type of instruments.
Laboratory sessions are aimed at developing experimental skills, practicing with the laboratory instrumentation described in the lectures and introduce a number of applications. The laboratory sessions focus on the following topics: uncertainty, frequency measurements, frequency synthesis with phase-lock loops, spectrum analysers.
Homework assignments presenting exam-like problems are aimed at encouraging a gradual study of the subject (optional, with approximate biweekly frequency).

Slide handouts on selected topics, exercises, homework assignments and laboratory manuals are available for download from the course website. There is no single reference textbook, but excerpts from the following additional texts are used as reference for specific topics:
JCGM 100:2008, Evaluation of Measurement Data – Guide to the Expression of Uncertainty in Measurement.
E. Rubiola, Phase Noise and Frequency Stability in Oscillators, Cambridge University Press, 2010.
A. Chenakin, Frequency Synthesizers, Artech House Inc., 2011.
P. Symons, Digital Waveform Generation, Cambridge University Press, 2014.
M. Engelson, Modern Spectrum Analyzer: Theory and Applications, Artech House Inc., 1984
R. A. Witte, Spectrum and Network Measurements, SciTech Publishing Inc., 2014.
L. Callegaro, Electrical Impedance: Principles, Measurement and Applications, CRC Press: Taylor and Francis, 2013.

Slide handouts on selected topics, exercises, homework assignments and laboratory manuals are available for download from the course website. There is no single reference textbook, but excerpts from the following additional texts are used as reference for specific topics:
JCGM 100:2008, Evaluation of Measurement Data – Guide to the Expression of Uncertainty in Measurement.
E. Rubiola, Phase Noise and Frequency Stability in Oscillators, Cambridge University Press, 2010.
A. Chenakin, Frequency Synthesizers, Artech House Inc., 2011.
P. Symons, Digital Waveform Generation, Cambridge University Press, 2014.
M. Engelson, Modern Spectrum Analyzer: Theory and Applications, Artech House Inc., 1984
R. A. Witte, Spectrum and Network Measurements, SciTech Publishing Inc., 2014.
L. Callegaro, Electrical Impedance: Principles, Measurement and Applications, CRC Press: Taylor and Francis, 2013.

The exam consists in a written test followed by an oral examination.
The written test (2h30min) is composed of two problems (15 points each) in which students have to analyse or design a measurement set-up, evaluating uncertainties and discussing sources of errors. The written test is open books and students can use a scientific calculator. The minimum pass grade for the written test is 18/30. The oral examination (30-45 min) consists of two open questions about the operation of devices and instruments described in the course and their uncertainties: the student is expected to present the most significant aspects of the topic in a coherent and autonomous way. The grades of the two parts are averaged to yield the final grade.
Students can optionally and individually deliver either a presentation (with slides) on one of the laboratory sessions of their choice or discuss a research paper (no slides, but the student can use their own notes on the paper). These optional activities (20-30 min) can grant up to 4 points to be added to the final grade.

The exam consists in a written test followed by an oral examination.
The written test (2h30min) is composed of two problems (15 points each) in which students have to analyse or design a measurement set-up, evaluating uncertainties and discussing sources of errors. The written test is open books and students can use a scientific calculator. The minimum pass grade for the written test is 18/30. The oral examination (30-45 min) consists of two open questions about the operation of devices and instruments described in the course and their uncertainties: the student is expected to present the most significant aspects of the topic in a coherent and autonomous way. The grades of the two parts are averaged to yield the final grade.
Students can optionally and individually deliver either a presentation (with slides) on one of the laboratory sessions of their choice or discuss a research paper (no slides, but the student can use their own notes on the paper). These optional activities (20-30 min) can grant up to 4 points to be added to the final grade.

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Corso Duca degli Abruzzi, 24 - 10129 Torino, ITALY

Corso Duca degli Abruzzi, 24 - 10129 Torino, ITALY