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Original title in Czech: Teoretická elektrotechnikaFEKTAbbreviation: PK-TEEAcad. year: 2013/2014
Programme: Electrical Engineering and Communication
Length of Study: 4 years
Profile
The doctor study programme is devoted to the preparation of the high quality scientific and research specialists in various branches of electrical engineering, namely in theory of electromagnetism, electrical circuits, general methods of signal processing and electrical measurements. The aim is to provide the doctor education in all these particular branches to students educated in university magister study, make deeper their theoretical knowledge, to give them also some practical knowledge for their individual scientific work.
Key learning outcomes
The doctors are able to solve scientific and complex engineering tasks from the area of electrical engineering and electromagnetism. Wide fundamentals and deep theoretical basis of the study program bring high adaptability and high qualification of doctors for the most of requirements of their future creative practice in all areas of electrical engineering. The doctors are competent to work as scientists and researchers in many areas of basic research or research and development, as high-specialists in the development, design, construction, and application areas in many institutions, companies, and organisations of the electrical and electronic research, development, and industry as in the areas of electrical services and systems, inclusively in the special institutions of the state administration. In all of these branches they are able to work also as the leading scientific-, research-, development- or technical-managers.
Occupational profiles of graduates with examples
Students who finish this study area are able to deal with scientific and complex engineering tasks from the sphere of general electrical engineering and electromagnetism. The PhD graduates are, owing to the developed high-quality theoretical education and specialization in the chosen field of study, sought as specialists in the area of general electrical engineering. In the sphere of general electrical engineering and electromagnetism, the PhD graduates will be competent to work as scientific and research workers in basic and applied research, as specialized development, construction and operation experts in various research and development institutions, electrotechnical and electronic production companies and corporations and with producers and users of electrical systems and devices, where they will be able to make use of modern computer and measurement techniques in a creative way.
Guarantor
prof. Ing. Jarmila Dědková, CSc.
Issued topics of Doctoral Study Program
The topic is divided into two sections. Within the first one, it is necessary to propose a comprehensive system methods and metrology for low-level magnetic measurements with respect to highly disturbed environments. It is suitable to focus on methods for achieving the S/N ratio <0.05 and enabling signal reconstruction. The proposed method should be used to describe a methodology for the verification of accuracy and repeatability of the evaluated results. Within the second section, the researcher is expected is carry out the description of the human body, its characteristics, and response to magnetic field changes. The set of appropriate tools comprises both deterministic and stochastic methods with the latest mathematical apparatus.
Tutor: Fiala Pavel, prof. Ing., Ph.D.
Electrical properties of materials we can obtain using different variants of impedance tomography algorithms. The input data are the measure data U-I (voltage-current) or B-I (magnetic field - current). The work is oriented to determine the sensitivity of reconstruction algorithms to input data obtained using different measurement ways. The aim of the research work is to find and experimentally verify the stable and not time-consuming algorithms with respect to required accuracy.
Tutor: Dědková Jarmila, prof. Ing., CSc.
In the Czech Republic, the investigation of sophisticated nanostructures constitutes one of the current scientific activities within basic research. The thesis presents various problems of the design, modelling, and experiments related to tuned nanostructures in the range of 10-500THz. The topic can be classified into three main areas. In terms of the content, the first of these fields is focused on the numerical modelling of structures based on real properties of nanomaterials. The second area comprises the design of methods and methodology for the verification of the experiments, the measurement, and the assumptions connected with the theoretical model. Through modelling via the finite element and the finite volume methods (realized using programs such as ANSYS, ANSOFT, or MAXWELL), a model of the mass dynamics behaviour is designed. The third field is closely related to technology; thus, the anticipated activities involve mainly the research of technologies to enable realization of the designed structures. In the experimental part of this area, practical feasibility of the structures is to be verified. The results are expected to support the investigation into special tuned periodic structures. The topics can be solved separately; the applicant will not be required to examine all the above-specified fields.
Students will be introduced with modern approaches to the modeling of tasks and wide spread spectrum signals in different structures. On the basis of relevant theories will be formulated model with a focus on the role of modeling of wide spectral signals in 3D structures. Numerical results are verified experimentally.
Tutor: Kroutilová Eva, doc. Ing., Ph.D.
Students will be introduced with modern approaches to the modeling of light engineering. The numerical models will be arranged the tasks based on the latest theories. The analysis of the student model features the possibility of using numerical methods in lighting technique and theory to application design.
The issue will focus on a numerical model of micro-and nano-structures of matter, the antenna design in GHz and THz frequency domain and the application of the model and its verification on the gel materials. Solution is a prerequisite for interest and ability to perform numerical models, orientation programming and monitoring trends in the given field.
Tutor: Bartušek Karel, prof. Ing., DrSc.
In the process of modelling, large-scale problems consisting in multiparametric tasks occur, featuring explicit description of the minimum of parameters. Numerical modelling offers certain approaches to such models. There exist two basic concepts, which can be characterized as deterministic and non-deterministic processes. Both these approaches are applicable in the numerical modeling of large-scale problems associated with complex tasks solved in electrical engineering or electronic and electromagnetic fields. When suitably formulated, these concepts become powerful tools in the scientific approach to basic and applied research. The aim of the doctoral thesis is to describe and define the two above-specified concepts and to experimentally verify the properties of the models. The testing will be realized on problems related to nanomaterial models.
The thesis is focused on the theoretical derivation of both deterministic and non-deterministic stochastic numerical models for regular differential equations. The individual steps involve modifications of the models for the numerical finite element, finite volume, and boundary element methods for static and dynamic models formulated by partial differential equations. The aim is to propose a stochastic model and to verify, using a simple example, the dynamic parameters for the electric discharge; in this context, the related effects will be evaluated utilizing a microscopic model of matter
Students will learn the use of modern light sources and basic physical principles modeling light. The selected model will be formulated principles of experimental light source. concept features namodelovaného sources will be verified experimentally. The analytical results will be evaluated and assessed by the use of solutions of light sources for different applications.
Students will be introduced with the principles and the use of modern light sources for extreme conditions (high intensity, extremely short exposure time, etc.) and approaches to their design and verification tasks. The light sources for specific extreme conditions will be designed based on the general evaluation of the basic model. The validity of theory and simulated reality is verified experimentally.