Detectors and sensors

lphys2102  2020-2021  Louvain-la-Neuve

Detectors and sensors
Due to the COVID-19 crisis, the information below is subject to change, in particular that concerning the teaching mode (presential, distance or in a comodal or hybrid format).
5 credits
22.5 h + 7.5 h
Q1
Teacher(s)
Cortina Gil Eduardo; Piotrzkowski Krzysztof;
Language
English
Main themes
- Study of basic techniques used in physical measurements : temperature, pressure, force, ...
- Study of the detection of ionizing radiations.
Aims

At the end of this learning unit, the student is able to :

1 a.     Contribution of the teaching unit to the learning outcomes of the programme (PHYS2MA)
AA1: 1.3, 1.4, 1.5, 1.6
AA2: 2.2, 2.3, 2.5
AA5: 5.1
AA6: 6.1, 6.4,
AA7: 7.1, 7.3
AA8: 8.1,8 .2
b.    Specific learning outcomes of the teaching unit
At the end of this teaching unit, the student will be able to:
1. define the characteristics of the fundamental sensors used in physics,
2. Identify and explain the physical processes related to these sensors.
3. select the appropriate reading system for elementary sensors.
4. define the characteristics of a radiation detector and describe its mode of operation:
5. identify and explain the physical processes associated with these detectors.
6. use, in an operational manner, the different types of detectors / sensors described during the teaching unit.
 
Content
Sensors.
1. Sensor fundamentals.
2. Measurement bridges (Wheatstone, Nerst, Sauty, Maxwell, Hay).
3. Voltage and current.
4. Temperature, pressure, humidity, vacuum.
5. Position and motion sensors.
6. Velocity, flow rate (in fluids).
7. Force, strain, mechanical shock, accelerometers.
8. Optical sensors.
9. Acoustic sensors.

Radiation detection.
1. Counting statistics.
2. Radiation sources.
3. Radiation-matter interactions.
4. General characteristics of detectors.
5. Gas detectors.
6. Semiconductor detectors.
7. Scintillation detectors.
8. Neutron detectors.
9. Nuclear electronics.

Laboratoires.
1. Introduction to simulation codes SRIM and VGATE .
2. Cyclotron : Bragg peak measurement.
3. Geiger-Mueller : counting statistics,.
4. NaI and HPGe : Gamma spectrometry.
5. Surface barrier detector : Alpha spectroscopy.
6. Neutron detection.
7. Sensor readout with RaspberryPI and/or Arduino.
Teaching methods

Due to the COVID-19 crisis, the information in this section is particularly likely to change.

This training has two activities:
1. Theory course and exercise sessions
- Lecture in audience
- Problem solving in audience
2. Mandatory practical work consisting of laboratories.
- Assembly and measurement
- Data analysis and report writing
All the material (syllabus, course slides, exercise lists, lab books, electronic components and tutorials for the simulation program) can be found on the MoodleUCL site of the teaching unit
Evaluation methods

Due to the COVID-19 crisis, the information in this section is particularly likely to change.

The evaluation is based on:
- reports from the laboratories,
- a written exam,
- a personal project.
Bibliography
Partie capteurs :
Jon S. Wilson, Sensor Technology Handbook .
J. Fraden, Handbook of Modern Sensors.

Partie radiation :
G.F. Knoll, Radiation Detection and Measurement.
C. Grupen & B. Schwartz, Particle Detectors (2nd Edition).
Faculty or entity
PHYS


Programmes / formations proposant cette unité d'enseignement (UE)

Title of the programme
Sigle
Credits
Prerequisites
Aims
Master [120] in Physical Engineering

Master [60] in Physics

Certificat universitaire de contrôle physique en radioprotection (Classe I)

Master [120] in Physics

Master [120] in Biomedical Engineering