CTU FEE Moodle
Biomedical sensors
B242 - Summer 2024/2025
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Biomedical sensors - BAB34BMS
| Credits | 4 |
| Semesters | Winter |
| Completion | Assessment + Examination |
| Language of teaching | Czech |
| Extent of teaching | 2P+2L |
Annotation
Sensors and microsensors used in biomedicine. Physical principles of operation of sensors and microsensors for sensing: temperature, pressure, deformation, vibration, mechanical quantities, magnetic field, flow, chemical and biochemical quantities, etc. Classification, parameters. Processing of sensor signals, application of sensors in biomedicine. Nanotechnology. Sensors and microsystems for biomedical diagnostics (Lab-on-chip, etc.).
Study targets
Overview of the use of modern sensors and microsensors, their applicability, especially in biomedicine.
Course outlines
1. Why sensors - functions of sensors, microsystems, actuators, sensor networks in biomedicine and the Internet of Things (IoT)
2. Sensor parameters
3. Capacitance - Capacitive sensors, pressure capacitive sensors
4. Piezoresistive effect - strain gauges, piezoresistive pressure sensors
5. Piezoelectric effect - sensors with the piezoelectric principle, piezoelectric pressure sensors
6. Inductance, inductance, magnetic principle, magnetostriction effect - sensors with magnetic circuits (inductances)
7. Hall effect, magnetoresistive effect - sensors of magnetic quantities
8. Temperature dependences of pn junctions, resistance of metals and semiconductors, thermoelectric effect, temperature dependence in MOS structures - temperature sensors
9. Accelerometers
10. Flow and level sensors
11. Sensors of chemical and biochemical quantities
12. Nanosensors
13. Sensor microsystems for biomedical diagnostics (lab-on-chip, etc.)
2. Sensor parameters
3. Capacitance - Capacitive sensors, pressure capacitive sensors
4. Piezoresistive effect - strain gauges, piezoresistive pressure sensors
5. Piezoelectric effect - sensors with the piezoelectric principle, piezoelectric pressure sensors
6. Inductance, inductance, magnetic principle, magnetostriction effect - sensors with magnetic circuits (inductances)
7. Hall effect, magnetoresistive effect - sensors of magnetic quantities
8. Temperature dependences of pn junctions, resistance of metals and semiconductors, thermoelectric effect, temperature dependence in MOS structures - temperature sensors
9. Accelerometers
10. Flow and level sensors
11. Sensors of chemical and biochemical quantities
12. Nanosensors
13. Sensor microsystems for biomedical diagnostics (lab-on-chip, etc.)
Exercises outlines
1.Introductory exercises - organization of exercises, introduction to laboratory equipment, safety in the laboratory
2.Measurement of task no. 1: Measurement of spectra
3.Measurement of task no. 2: Magnetic field sensors
4.Measurement of task no. 3: Piezoresistive (piezoresistive) force sensors
5.Measurement of task no. 4: Metal detectors
6.Measurement of task no. 5: MEMS accelerometers
7.Measurement of task no. 6: Optical sensor, optical barrier, optical encoder
8.Measurement of task no. 7: Temperature sensors
9.Measurement of task no. 8: Wireless power supply and communication for biomedical implants
10.Measurement of task no. 9: Peltier element and thermocouple
11.Measurement of task no. 10: Capacitive distance sensors
12.Measurement of task no. 11: Chemical sensors
13.Credit test, re-measurement of tasks
14.Revised test, credit
2.Measurement of task no. 1: Measurement of spectra
3.Measurement of task no. 2: Magnetic field sensors
4.Measurement of task no. 3: Piezoresistive (piezoresistive) force sensors
5.Measurement of task no. 4: Metal detectors
6.Measurement of task no. 5: MEMS accelerometers
7.Measurement of task no. 6: Optical sensor, optical barrier, optical encoder
8.Measurement of task no. 7: Temperature sensors
9.Measurement of task no. 8: Wireless power supply and communication for biomedical implants
10.Measurement of task no. 9: Peltier element and thermocouple
11.Measurement of task no. 10: Capacitive distance sensors
12.Measurement of task no. 11: Chemical sensors
13.Credit test, re-measurement of tasks
14.Revised test, credit
Literature
copies of course lectures
lecture notes
Sergey Y. Yurish: Sensors and Applications in Measuring and Automation Control Systems, (Book Series: Advances in Sensors: Reviews, Vol. 4 ), Publisher: IFSA Publishing, S.L. (Barcelona, Spain)I SBN: 978-84-617-7597-2
Sabrie Soloman: Sensor Handbook, McHraw Hill, 2010, ISBN: 978-0-07-160571-7
Tagawa Tatsuo: Biomedical Sensors and Instruments, 2011, ISBN13 (EAN): 9781420090789
Jones, Deric P.;Watson, Joe: Biomedical Sensors, 2010, ISBN / EAN 9781606500569 / 9781606500569
Andrew G. Webb: Principles of Biomedical Instrumentation, Cambridge University Press, 2018, EAN: 9781107113138ISBN: 110711313X
Husák,M.: Mikrosenzory a mikrosystémy, Academia 2008
Ďaďo - Kreidel: senzory. ČVUT 1999
lecture notes
Sergey Y. Yurish: Sensors and Applications in Measuring and Automation Control Systems, (Book Series: Advances in Sensors: Reviews, Vol. 4 ), Publisher: IFSA Publishing, S.L. (Barcelona, Spain)I SBN: 978-84-617-7597-2
Sabrie Soloman: Sensor Handbook, McHraw Hill, 2010, ISBN: 978-0-07-160571-7
Tagawa Tatsuo: Biomedical Sensors and Instruments, 2011, ISBN13 (EAN): 9781420090789
Jones, Deric P.;Watson, Joe: Biomedical Sensors, 2010, ISBN / EAN 9781606500569 / 9781606500569
Andrew G. Webb: Principles of Biomedical Instrumentation, Cambridge University Press, 2018, EAN: 9781107113138ISBN: 110711313X
Husák,M.: Mikrosenzory a mikrosystémy, Academia 2008
Ďaďo - Kreidel: senzory. ČVUT 1999
Requirements
Basic knowledge of the operation of electronic circuits (operational amplifier in application circuits, bridge circuits, etc.), basic knowledge of physical phenomena, basics of mathematical analysis. Derivation of equations is not required, the subject is practically oriented.