| CODE | 56915 |
|---|---|
| ACADEMIC YEAR | 2023/2024 |
| CREDITS |
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| SCIENTIFIC DISCIPLINARY SECTOR | ING-IND/12 |
| LANGUAGE | Italian |
| TEACHING LOCATION |
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| SEMESTER | 2° Semester |
| TEACHING MATERIALS | AULAWEB |
Measurement systems constitute a key enabling technology for industry, transportation, energy and environment.
Their design is thus considered, from the architecture, to their main functions, including data acquisition, processing and sharing through networks.
Measurement systems devoted to the monitoring and control of motion - either artificial, as in manufacturing and in robotics, or natural, as in biomechanics and in sea waves - are studied in detail.
Design of measuring systems, including the selection of components and architectures and the development of software for data acquisition, data processing and automatic control. Measurement of motion, forces and acoustic phenomena. Basics of signal processing.
Comprehension of the fundamental components in a measurement system and capability of identifying their criticalities and strengths, according to a specific application.
Development of skills in signal processing, including spectral analysis and signal filtering.
Selection of measurement system architectures for specific applications monitoring or automatic-control applications.
Programming of data acquisition in the LabView ® environment, for monitoring and control
Lectures and laboratory practice, including a training in the use of state-of-the-art data acquisition systems.
The measuring system as a communication system. Conditioning of input signals: power sources, oscillators, instrumentation amplifiers, current transmission, interfacing criteria. Data acquisition boards. Microcomputers in measuring systems: hardware, software, connectivity. Data acquisition: programming (LabView) and management of data acquisition, for process monitoring and for automatic control. Processing of measurement signals: spectrum analysis and digital filtering (outline). Instrumentation networks; remote control of measuring systems. Architectures of digital measuring systems.
Design and implementation of a position servo-system and of a remote vibration-monitoring system.
Measurement of motion and forces. Case studies.
Example of representative references include the following:
Bentley, Principles of measurement systems, Prentice-Hall, 2005
G.B. Rossi, Measurement and Probability, Springer, 2014
Additional references will be provided, according to the needs of the students.
Office hours: By appointment (g.b.rossi@unige.it)
Office hours: By appointment: marta.berardengo@unige.it
GIOVANNI BATTISTA ROSSI (President)
VITTORIO BELOTTI
GIANCARLO CASSINI
FRANCESCO CRENNA
MARTA BERARDENGO (President Substitute)
All class schedules are posted on the EasyAcademy portal.
Written admission test and exam interview, including discussion of a design report, based on lab experience.
Students with SLD, with disabilities, or with other regularly certified special educational needs will agree with the teacher on the exam method and the compensatory instruments, by contacting the instructor at least 10 days before the exam. They will also be able to take advantage of the additional time required by law.
The written test aims to ascertain the acquisition of design skills.
The design report should demonstrate proficiency in laboratory practice and the capability of preparing a report according to current professional guidelines.
The exam interview aims to ascertain proper understanding of course topics.
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