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Second Semester 
Teaching style
Lingua Insegnamento

Informazioni aggiuntive

Course Curriculum CFU Length(h)


The Course aims at providing basic knowledge in the field of Electrical and Electronic Measurements and introduce modern measurement equipment, signal conditioning and digital instruments. Continuous learning is favored by means of technical literature, manuals of manufacturers, technical standards and the law.


The knowledge of theory of electric circuits is required (in particular the following subjects: lumped circuits, steady state circuits, circuits in sinusoidal regime, filters, circuit analysis in dynamic operation). Basic concepts of system analysis are also suggested.


Introduction (2 hours)
Introduction to the course and to its specific educational goals. Description of teaching material and of exam tests.
Fundamental concepts of measurements (10 hours)
Fundamental elements of a measurement. Measurement Errors. Errors in direct and indirect measurements. Measurement traceability. International metrology organization. The International System of measurement units. Measurement uncertainty. Elements of statistics and probability. Type A and Type B uncertainty evaluation. Uncertainty propagation Expanded uncertainty. Compliance tests.
Basic electrical measurements (4 hours)
Measurement of DC voltages and currents. Load and insertion effects. Measurement of AC quantities. Root Mean Square (RMS) and power.
Analog signal processing. (3 hours)
Circuits with operational amplifiers. Signal conditioning. Rectifiers. True RMS converters.
AD and DA Conversion (8 hours)
Sampling and quantization. Input-Output diagrams. Quantization noise. Weighted network and R/2R DA converters. Dual ramp, successive approximations, flash and pipeline AD converters. Sample & hold. Specifications of AD and DA converters.
Digital multimeters (4 hours)
Block diagram. Measurement of voltage, current and resistance. Specifications of multimeters.
Data acquisition systems (6 hours)
Single-channel and multi-channels systems. Communication between instruments and computers. Virtual Instrumentation.
Analog oscilloscope (4 hours )
Cathode ray tube. Vertical channel and time basis. The trigger. Dual trace oscilloscopes Voltage probes.
Digital oscilloscope (4 hours )
Operation and performance. Real-time and equivalent-time sampling.
Time and frequency measurements (4 ore)
Circuits for time and frequency measurements. Universal counter. Binary and BCD counter. Errors in time and frequency measurements.
Analysis in the frequency domain (10 hours )
Sampling theorem and aliasing. Signal truncation and spectral leakage. The Discrete Fourier Transform and its practical aspects in measurement systems. Super-heterodyne spectrum analyzers. FFT spectrum analyzers.
Differential input circuits (2 hours)
Differential amplifier. Instrumentation amplifier.
Disturbances in electronic measurements (5 hours)
Common and ground connections. Inductive and capacitive coupling. Shields. Measurement noise.
Laboratory and experimental work (24 hours)
E1 - Uncertainty analysis. ISO GUM Standard. Data series analysis. Statistical parameters evaluation. Presentation of results: significant digits.
E2 - Digital multimeter. Alternating and continuous voltage measurement. Frequency spanning. Resistance measurement (2wire and 4wire set up). Frequency behavior.
E3 - Oscilloscope. Probe compensation. Voltage and current characteristic evaluation in electric bipole. Example for rectifier diode. Use of a digital storage oscilloscope. Acquisition of transient events.
E4 - Virtual Instruments. Introduction to virtual instruments.
E5 - Data acquisition systems. Use of data acquisition boards. Analysis and performance of basic Virtual Instruments (VI).
E6 - Analysis of signals in the frequency domain. Virtual instruments for frequency analysis. Practical aspects of sampling and signal truncation. Observation windows.

Teaching Methods

The course has an overall duration of 90 hours. 66 hours consist of lessons and classroom exercises, during which the teacher presents the subjects indicated in the program and discusses some numerical examples. The remaining 24 hours involve experimental work in the laboratory, where the students, supervised by the teacher, use the basic measurement instrumentation (multimeters, oscilloscopes, data acquisition boards managed through virtual instruments).
Teaching will be delivered in person. The lessons can be integrated with audiovisual materials and streaming.

Verification of learning

The acquisition of the learning outcomes is verified through a single oral exam, during which students are asked to discuss some of the topics covered in the course, possibly with the help of simple numerical examples.
The score of the examination is provided by a grade out of thirty. To pass the exam, thus reporting a mark of not less than 18/30, the student must demonstrate a basic knowledge of all the topics discussed. To achieve a score of 30/30 with honors, the student must demonstrate an excellent knowledge of the topics discussed.
The assessment takes into account the capacity of both present with rigor and effectiveness the theoretical subjects and highlight their practical aspects.


1. Notes of the teacher, available at:
2. M. Savino: Fondamenti di scienza delle misure. Nuova Italia Scientifica, 1992
3. U. Pisani: Misure Elettroniche. POLITEKO Edizioni, 1999
4. G. Iuculano, D. Mirri: Misure Elettroniche. CEDAM, 2002

More Information

Supplementary teaching material (slides used in some in-depth lessons, exercises, data from manuals and catalogs) is available on

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