Non-Destructive Diagnostics and Physics of Dielectrics
FEKT-MPA-NDDAcad. year: 2020/2021
The course focuses on two areas of modern diagnostic materials, i.e. dielectric spectroscopy and acoustic and electromagnetic emission.
Emphasis is put on the understanding of the issues, applying relevant knowledge and practical experience with diagnostic materials.
The following topics are demonstrated during a semester:
physical laws accompanying the behavior of dielectrics and insulators in electric field polarization happening in dielectrics, the behavior of materials in the DC and AC electric field, the fundamental aspects of conductivity, dielectric absorption, dielectric loss and dielectric strength materials. Furthermore, the basic types of electrical insulating materials due to their being sorted resistance degradation factors, in particular the temperature and electrical stress.
In the area of acoustic and electric emissions will be:
The emergence and spread of acoustic signals and electromagnetic emissions, types of diagnostic sensors, types of defects in composite systems, analysis of noise spectra using low-noise amplifiers, suitable measurement techniques and shielding systems.
Students will enhance skills in diagnostics of materials, analysis of dielectric spectra analysis of noise spectra, programming in Matlab and communication over the GPIB and RS 232
Learning outcomes of the course unit
- Describe different types of polarization in dielectric materials
- Name of the principles of polarization and to estimate the frequency dependence of the dielectric spectrum
- Identify defects in the dielectric systems and identify degradation processes in materials
- Describe the various noise spectrum and assess the impact of noise on the characteristics of the components
- Create a replacement model of passive and active components
- Define the causes of acoustic or electromagnetic emissions and create a mathematical model
- Implement basic acoustic emission measurements
- Create a measurement algorithm in Matlab communication with the GPIB, RS232 and TCP
Students should be able to explain the basic physical phenomena, analyze simple electronic circuits, know basic programming algorithms in Matlab or C + +.
General knowledge is required at the level of bachelor's degree and valid examination for qualifying workers for an independent activity (within the meaning of § 6 of the Decree).
Recommended optional programme components
Recommended or required reading
Ambrózy, A.: Electrical Noise, Budapest, Academia, 1982,
Buckingham, M.J. : Noise in Electronics Devices and Systems, London, John Willey, 1983,
Havriliak, S. Jr., Havriliak, S. J: Dielectric and Mechanical Relaxation in Materials: Analysis, Interpretation and Application to Polymers, Hanser/Gardner Publications, Inc., Cincinnati & Carl Hanser Verlag, München, 1997
Böttcher, C. J. F., Bordewijk, P.: Theory of Electric Polarization, 2. ed., Amsterdam, Elsevier, 1978,
Hawkins, W. L.: Polymer Degradation and Stabilization, 1. ed., Berlin, Springer-Verlag, 1984,
Hedvig, P.: Dielectric Spectroscopy of Polymers, Budapest, Akadmiai Kiadó & Adam Hilger, 1977,
Jellinek, H. H. G.: Aspects of Degradation and Stabilization of Polymers, 1. ed., Amsterdam, Elsevier, 1978,
Jonscher, A. J. K.: Dielectric Relaxation in Solids. 1. ed., London, Chelsea Dielectric Press, 1983
Planned learning activities and teaching methods
Teaching methods depend on the type of course unit as specified in the article 7 of BUT Rules for Studies and Examinations. They include lectures, excercises and practical laboratories. Course is taking advantage of e-learning (Moodle) system.
Assesment methods and criteria linked to learning outcomes
- Evaluation of laboratory exercises - 20 b (total 4 reports)
- Unspecified - 30 b (2 semester work with the defense)
- Final exam - 50 b
Language of instruction
1. Electric fields, induction, introduction to dielectric spectroscopy
2. Dipole moment, dielectric insulator
3. Dielectric polarization in both AC and DC pole
4. The mathematical description of dielectric materials
5. Behavior dielectric spectra depending on the temperature, pressure and humidity
6. Description relaxation processes and their interpretation
7. Acoustic emission, historical development, wave longitudinal, transverse
8. Acoustic emission sensors, instrumentation for measuring acoustic signal.
9. Parameters for assessment, fault isolation.
10. Acoustic emission in composites, acoustic emissions in building materials.
11. Electromagnetic emissions, its interpretation sensor.
12. Methods to increase the immunity measuring systems.
- Obtain a general overview of the use of dielectric spectroscopy in materials science and other fields of engineering,
- Obtain a general overview of the use of acoustic and electromagnetic emissions in materials science and other fields of engineering,
- Define the basic aspects of the analysis of dielectric materials
- Identify the basic dielectric spectrum and propose a suitable mathematical method
- Define the basic characteristics of the noise
- Identify a characteristic noise and identify corrective measures for passive components
- Create measurement algorithms with conventional measuring instruments on the GPIB, RS232, TCP
Specification of controlled education, way of implementation and compensation for absences
The content and forms of instruction in the evaluated course are specified by a regulation issued by the lecturer responsible for the course and updated for every academic year.
Classification of course in study plans