Intelligent Sensors

• 26 hrs lectures
• 4 hrs exercises
• 4 hrs laboratories
• 18 hrs projects

• 55 pts final exam (35 pts written part, 20 pts test part)
• 15 pts mid-term test (9 pts written part, 6 pts test part)
• 4 pts numeric exercises
• 4 pts labs
• 22 pts projects

The the acquainted knowledge belongs the measurement of physical quantities, how to convert physical quantities to electronic form using sensors and how to transmit, process, and use acquired data. Everything is oriented on intelligent sensors, sensor networks and smart homes.

To inform about the measurement of the physical quantities. To learn how the physical quantities are converted to an electronic form using sensors. To learn how to transmit, process and use data.

Valid schooling of Edict No. 50 (work with electrical devices) is needed.

• Cai, Z.X.: Intelligent Control: Principles, Techniques and Applications, World Scientific, ICIA Vol. 7, 1997, p. 451, ISBN 981-02-2564-4.
• Yamasaki, H.: Intelligent Sensors, Elsevier, 1996, p. 298, ISBN 0-444-89515-9.
• Martinek, R.: Senzory v průmyslové praxi, BEN - technická literatura, 2004, ISBN 80-7300-114-4
• Švec, J.: Příručka automatizační a výpočetní techniky, SNTL, 1975
• Fraden, J.: Handbook of Modern Sensors: Physics, Designs, and Applications, AIP Press, 2003, ISBN 0387007504
• Frank, R.: Understanding Smart Sensors, Artech House Publishers, 2000, ISBN 0890063117
• Brignell, J., White, N.: Intelligent Sensor Systems (Sensors), Institute of Physics Publishing, 1994, ISBN 0750302976
• Ristic, L.: Sensor Technology and Devices, Artech House Publishers, 1994, ISBN 0890065322

1. Introduction - sensors, types of sensors, their parameters. Microelectronic and microelectromechanic systems.
2. Electrical conductibility in different materials and components for the sensor production (semi-conductors, diodes, transistors, ...), brief introduction to the sensor production.
3. Selected types of the measurement of the physical quantities (position estimation, measurement of the pressure, flow, temperature, optical, electrical, chemical, and magnetic quantities).
4. Basic sensing principles (function and physical principles) - how do the sensors work?
5. Sensor data acquirement. Basic principles of the acquirement and transmission of the data (signals and buses).
6. Data processing. Pattern recognition and classification.
7. Intelligent sensors I. Definitions, examples.
8. Intelligent sensors II. Complex sensors, biometric sensors (fingerprint scanners, retina scanners, etc.).
9. Soft-Computing (fuzzy logic, neural networks, agents), use in the intelligent sensors.
10. Sensor networks I. Centralised and decentralised system of the measurement chains. Communication (IEEE 1415), distributed systems.
11. Sensor networks II. Sensor networks as a multiagent systems.
12. Practical examples of the intelligent sensors.
13. Future of the intelligent sensors, trends (nanosensors, biosensors).

1. Theoretical calculations - measurement, errors.
2. Theoretical calculations - selected measurement processes.

1. Work with elementary sensors. Practical examples.
2. Work with complex sensors. Practical examples.

1. Processing of a project from the selected part of the course.

1. Written midterm test
2. Participation and active work in laboratories + exercises
3. Project (minimum are 3 points)

Exam prerequisites:

Student must gain at least 15 points during the term. Minimum for the project are 3 points.

In the case of missed HW laboratories it is possible to replace them until the laboratory is ready for further laboratory practice. Please inform the head of the laboratory or the course supervisor without any delay.

Student must gain at least 15 points during the term. Minimum for the project are 3 points.