Sensors and Measurement
| Type of study | Bachelor |
|---|---|
| Language of instruction | Czech |
| Code | 450-2003/03 |
| Abbreviation | SaM |
| Course title | Sensors and Measurement |
| Credits | 4 |
| Coordinating department | Department of Cybernetics and Biomedical Engineering |
| Course coordinator | prof. Ing. Petr Bilík, Ph.D. |
Subject syllabus
Lectures:
1.Introduction to the nonelectrical quantities measurement. Role and position of sensors in measurement and control systems. Generation of sensors and their classification.
2.Physical and mathematical model of sensor. Statical and dynamical properties of sensors.
3.Transfer of information from sensor. Connection wiring influence. Unification of sensor signals. Method of correction of sensor characteristic.
4.Physical principles of sensors. Resistance position sensors. Strain gauges. Resistance temperature detectors (RTDs).
5.Capacitive-type, inductance-type and inductive-type sensors.
6.Magnetic, piezoelectric and pyroelectric sensors. Thermoelectric sensor.
7.Photoelectric sensor. Radiation pyrometers. Thermovision.
8.Microelectronic sensors. Integrated and SMART sensors. The influence of sensor technology to their design. MEMS sensors.
9.Position and movement measurement. Level measurement.
10.Force and strain measurement. Acceleration measurement. Pressure and vacuum measurement.
11.Gas and fluid flow measurement.
12.Temperature measurement. Heat consumption measurement.
13.Visible light and nuclear-particle radiation measurement.
14. Chemical quantities measurement. Gas and liquid composition measurement. Humidity measurement pH measurement. Emission measurement.
Laboratories:
1.Laboratory code introduction, safety training
2.Static characteristic of resistance position sensor. Load and connecting wiring influence on the static characteristic.
3.Dynamic characteristic of thermocouple. The influence of thermocouple design to the dynamic characteristic.
4.Elimination of temperature sensitivity of strain gauge.
5.The influence of negative feedback on sensor characteristic. Magnetoelectric sensor for current measurement.
6.Consultation for lab excercises.
7.Substitute lab lesson.
8.Rotational velocity measurement. The demonstration of influence of sensor presence to measurement system
9.Capacitive sensors. The influence of connecting wiring on statical characteristic. Signal and transmition to the processing unit.
10.Photoelectrical position sensors. Incremental shaft enconders. Digital shaft encoder.
11.Heat consumption measurement.
12.Microelectronic accelerometer.
13.Imaging CCD sensors. Transmition of information from imaging sensor and their processing.
14.Consultation for lab excercises. Substitute lab lesson.Credit.
1.Introduction to the nonelectrical quantities measurement. Role and position of sensors in measurement and control systems. Generation of sensors and their classification.
2.Physical and mathematical model of sensor. Statical and dynamical properties of sensors.
3.Transfer of information from sensor. Connection wiring influence. Unification of sensor signals. Method of correction of sensor characteristic.
4.Physical principles of sensors. Resistance position sensors. Strain gauges. Resistance temperature detectors (RTDs).
5.Capacitive-type, inductance-type and inductive-type sensors.
6.Magnetic, piezoelectric and pyroelectric sensors. Thermoelectric sensor.
7.Photoelectric sensor. Radiation pyrometers. Thermovision.
8.Microelectronic sensors. Integrated and SMART sensors. The influence of sensor technology to their design. MEMS sensors.
9.Position and movement measurement. Level measurement.
10.Force and strain measurement. Acceleration measurement. Pressure and vacuum measurement.
11.Gas and fluid flow measurement.
12.Temperature measurement. Heat consumption measurement.
13.Visible light and nuclear-particle radiation measurement.
14. Chemical quantities measurement. Gas and liquid composition measurement. Humidity measurement pH measurement. Emission measurement.
Laboratories:
1.Laboratory code introduction, safety training
2.Static characteristic of resistance position sensor. Load and connecting wiring influence on the static characteristic.
3.Dynamic characteristic of thermocouple. The influence of thermocouple design to the dynamic characteristic.
4.Elimination of temperature sensitivity of strain gauge.
5.The influence of negative feedback on sensor characteristic. Magnetoelectric sensor for current measurement.
6.Consultation for lab excercises.
7.Substitute lab lesson.
8.Rotational velocity measurement. The demonstration of influence of sensor presence to measurement system
9.Capacitive sensors. The influence of connecting wiring on statical characteristic. Signal and transmition to the processing unit.
10.Photoelectrical position sensors. Incremental shaft enconders. Digital shaft encoder.
11.Heat consumption measurement.
12.Microelectronic accelerometer.
13.Imaging CCD sensors. Transmition of information from imaging sensor and their processing.
14.Consultation for lab excercises. Substitute lab lesson.Credit.
E-learning
Materials are available at https://lms.vsb.cz/?lang=en.
Literature
1.KREIDL, Marcel. Technická diagnostika: senzory, metody, analýza signálu. 1. vyd. Praha: BEN, 2006, 406 s. Senzory neelektrických veličin. ISBN 80-7300-158-6.