Study programme priemyselná elektrotechnika

Basic information

Study programme in national registry: priemyselná elektrotechnika
Guaranted by: Faculty of Electrical Engineering and Informatics
Study field: Electrical and Electronics Engineering
Level of degree: 3
Form of study: present
Degree: PhD.
Length of study in years: 4
Professionally oriented: No
Joint study programme: No
Languages of delivery: english language, slovak language

Graduate profile

Description
A graduate of the 3rd degree of the study program Industrial electrical engineering has knowledge in the field of selected specific parts of mathematics, applied informatics, physics and theoretical electrical engineering, theoretical electrical engineering, and electronics, related to the focus of the topic of the final thesis, which is followed by specific professional disciplines from the areas of specialization electrical energy, electronic systems and signal processing, electrotechnical systems, industrial electrical engineering, technologies in automotive electronics, multimedia communication technologies. The graduate applies the principles of independent creative and scientific activity in the field of industrial electrical engineering and is able to find solutions to problems, taking into account ethical and social aspects. He is able to independently solve research problems, cooperate with foreign countries and use the world's professional literature. The graduate acquires the ability to analyze the economic and ecological connections of technical works and processes from the field of specialization, the ability to scientifically research and bring own solutions for theory and professional practice is the ability to lead a scientific, development, and professional team is able to follow the latest developments in his field, has the ability take professional and scientific positions. He is able to perform independent creative and scientific activities associated with designing, developing, managing, and ensuring the operation and servicing of electrical machines, devices, and modern electrical and electromechanical systems. He can handle activities in the field of material structures and systems as well as a wide range of production technologies in electrical engineering. Furthermore, it will be applied in the field of electronics, advanced methods of signal processing, and complex measuring and testing systems for electronics.
Learning objectives
A graduate of the 3rd degree of the Industrial Electrical Engineering study program will acquire the necessary theoretical and practical knowledge, skills and competences in the field of Electrical Engineering in the field of theoretical and high-current electrical engineering, electric power engineering, electronics and electrical technologies and materials. The graduate applies a systematic understanding of the field of electrical engineering in order to acquire the skills and methods of scientific research and familiarize himself with the current state of knowledge in the field of electrical engineering. He can apply and creatively improve and develop theories and research, development and innovation procedures in the field and create new ones, he can identify global scientific and innovative developments in the field and in related fields and use it in the direction and development of the field. In a broader context, in relation to the long-term impact in the given field, the graduate is capable of critical analysis, evaluation, and synthesis of new complex concepts in a broader context. In relation to the long-term impact in the given area and from the point of view of social, ethical, environmental, and other criteria, he is ready to formulate information about the outputs and conclusions of scientific, research, and development work at the international level and to manage large-scale research tasks and teams. The intention is to develop key knowledge, skills, and competencies in graduates so that: - was considered an expert in his field, who will contribute to technical development and social progress either in scientific research or in professional practice, - demonstrated a systematic understanding of the field of study and mastered the skills and methods of scientific research associated with the given field corresponding to the current state of knowledge, - demonstrated the ability to conceive, construct, implement and edit a substantial part of the research with scientific integrity, - contributed to expanding the boundaries of scientific knowledge by realizing an extensive set of works, some of which are worthy of peer-reviewed publication of the national or international level, - was capable of critical analysis, evaluation, and synthesis of new and complex concepts, - was able to communicate his area of expertise with the wider scientific community and the lay public, - was able to support technical, social, and cultural progress in a knowledge-based society in an academic and professional context. The scientific erudition of a highly qualified expert in scientific research, development, and practice mainly refers to: - modeling of elements in the power system, methods of analysis of power systems, wave processes on lines, modeling and calculations of electromagnetic fields, surface phenomena in electric power transmission, electromagnetic transients, and compatibility, - the use of elements of artificial intelligence in the management of the electricity system, information and control systems, stability of the electricity system, one-way transmissions of electricity, degradation processes of the equipment of the electricity system, specifics of TVN in one-way transmission lines, problems of rationalization of electricity consumption, - power and digital electronics, actuators and drives, systems and methods of automatic and intelligent control for designing, constructing, and maintaining large-scale technical solutions, including electrotechnical systems, complex electrotechnical systems, design, and engineering of the most modern electromechanical devices, - modern electronic systems, i.e., complex, intelligent electronic devices that work based on communication with another device, complex, intelligent electronic systems are based on the integration of knowledge from the field of electronic circuits, signal processing methods, sensors, information, and communication technologies (e.g., smartphones, smart TV receivers, smart homes, assistance service systems for motor vehicle drivers, selected medical electronics devices, radar systems, human-machine voice communication systems, terminal devices for the concept of the so-called Internet of Things, sensor networks in cars, sensor networks for monitoring the state of the environment, intelligent measurement and monitoring systems, etc.) - industrial systems using electromagnetic, magnetic, electrodynamic, or electrostatic phenomena, also analysis of modern linear and non-linear electrical circuits, - comprehensive knowledge in the area of identification of material, technological and other parameters, also in the conditions of limit states, will enable the graduate to use them in production technologies in electrical engineering.
Main learning outcomes
Graduate of the 3rd degree of the Industrial Electrical Engineering study program: - He has extensive knowledge in the field of theoretical and high-current electrical engineering, electric power engineering, electronics, and electrical technologies and materials. - He has skills in the field of scientific research based on critical analysis and synthesis, he masters the process of acquiring new scientific knowledge when conducting basic and applied research in the field of industrial electrical engineering in the electrical engineering field of study. He is able to demonstrate a deep systematic understanding of the field of industrial electrical engineering. He is able to conceive, construct, implement and modify theories, sophisticated methods, and procedures of science at a level corresponding to international criteria in the field of industrial electrical engineering. He has a systematic, comprehensive, and complex set of knowledge from several areas of the study field of electrical engineering, which serve him as a basis for carrying out research and development and creating new knowledge in the field of industrial electrical engineering, high-current electrical engineering, electric power engineering, electrical technologies and materials, power and signal electronics, control hardware systems, microelectronics, nanoelectronics and measuring technology. He uses this knowledge in training new experts. He is able to carry out a substantial part of the research himself, outline it, construct it, implement it, optimize it, and all this in an ethically pure way. The graduate can actively acquire new knowledge and information, critically analyze and reevaluate it, and use it in theory and in practical applications for the development of the electrical engineering field of study. The graduate can formulate new hypotheses and strategies for further research and development of the field of study. He applies his own findings of his theoretical analysis and his complex scientific research to solve problems in this area. Based on his outputs and findings, he can design, verify and implement new research and work procedures. He practically controls the selected research methods and uses them in the search for new technologies and materials, production methods and procedures that are new to industrial electrical engineering, and in the search for technical details and important interactive system links. - He is able to incorporate the outputs from research and development as an idea, idea, product, or process into the production program of an industrial enterprise or apply them in another way in practice. He can carry out research, analysis, measurements, data collection, and processing, and he can use advanced methods and tools for computer modeling and process simulations. The graduate is characterized by independent, critical, and analytical thinking with a subsequent synthesis of new ideas and innovative procedures, which he applies in changing conditions. He can plan, and initiate the solution of complex problems, including the formulation of goals, means, and methods. It takes social, scientific, and ethical aspects into account when formulating research objectives and interpreting research results. Independently presents and communicates the results of research and development before the professional community. Through original research, he contributes to expanding the boundaries of scientific knowledge of electrical engineering with a focus on industrial electrical engineering, which he proves through the realization of an extensive set of works, including the publication of scientific works peer-reviewed by internationally recognized experts. Significantly contributes to technical development and social progress either in scientific research or in professional practice by formulating engineering-physical-technological problems and can bring their solutions to practical realizations, has qualified skills to independently solve scientific projects and lead a team of experts, determine the focus of research and coordinate the implementation team in the field of electrical engineering.
Professions
Professions for which the graduate is prepared at the time of completion.

Employability

Evaluation of the study programme graduates employability
According to the official material from 1.6. 2022 from the Sector-driven Innovation project provided by Trexima, the education in the Electrical Engineering study program is the 14th best out of 209 technical in Slovakia related to the Sector Council for Energy, Gas, and Electricity. The project is implemented in cooperation with the Republican Union of Employers, the Association of Employers' Unions of the Slovak Republic, the Association of Industrial Unions and Transport, the Ministry of Labour, Social Affairs and the Family, the Association of Cities and Towns of Slovakia, the Confederation of Trade Unions. Rank School Department Overall rating 1 STU in Bratislava - Faculty of Electrical Engineering and Informatics, Electrical Power Engineering 100 2 STU in Bratislava - Faculty of Electrical Engineering and Informatics Cybernetics - Robotics and Cybernetics 99.5192 3 STU in Bratislava - Faculty of Electrical Engineering and Informatics automation - automation and control 99.0384 4 University of Applied Sciences in Žilina - Faculty of Electrical Engineering, high-current electrical engineering 98.5576 5 TU in Košice - Faculty of Electrical Engineering and Informatics, Electrical Power Engineering 98.0769 ... 11 University of Žilina in Žilina - Faculty of Mechanical Engineering, Industrial Engineering 95,1923 12 Comenius University - Faculty of Mathematics, Physics and Informatics. physics - nuclear and subnuclear physics 94.7115 13 University of Žilina in Žilina - Faculty of Electrical Engineering automation - applied telematics 94.2307 14 Technical University of Košice - Faculty of Electrical Engineering and Informatics theoretical electrical engineering - industrial electrical engineering 93.75 Year: 2018, 2019 application data is not available Source: https://uplatnenie.sk/?degree=V%C5%A0&vs=709000000&faculty=709040000&field=2602V02&year=2018 Source: https://uplatnenie.sk/?degree=V%C5%A0&vs=709000000&faculty=709040000&field=2602V02&year=2019
Evaluation of the study programme quality by employers
Based on the statements of authorities from practice and the knowledge gained during the discussion within the Council meeting of the study program Industrial Electrical Engineering, 3rd level, full-time form (hereinafter SP), representatives of external parties from practice welcome and support the existence and development of SP, which is characterized not only by narrow by focusing on specialization in the field of industrial electrical engineering, but also by a certain degree of interdisciplinarity within the field of electrical engineering, which enhances the fact that the pedagogical activity is covered by several departments of the faculty. Graduates find employment not only in various areas of industrial electrical engineering but also in other job positions and specializations in electrical engineering. From the point of view of employers, there was, is, and will be an interest in applying the graduates of the mentioned study program in practice. There is already a serious lack of qualified experts in this field, which is beginning to cause problems with filling vacant positions and which, to some extent, hinders the faster development of the industry in the field of industrial electrical engineering and related fields of electrical engineering in Slovakia and especially in the Eastern Slovak region. Employers see a high need for the aforementioned study program for practice and guarantee employment for all successful graduates if they are interested in working in the given field. Statements of authorities from practice are available in the Appendices to the study program folder in the system https://res.tuke.sk/forms/osp/sp/100127

Structure and content of the study programme

Suggested study plan in the MIAS portal

Current academic year plan and current schedule

Current academic year plan
Current schedule: MAIS portal

Persons responsible for the study programme

Person responsible for thequality of the study programme: prof. Ing. Juraj Kurimský, PhD.
List of persons responsible for the profile courses: Study advisor: doc. Ing. Jaroslav Džmura, PhD.
Student representatives: Ing. Marek Bobček
Study department

Spatial, material, and technical provision of the study programme and support

List and characteristics of the study programme classrooms
The laboratory of measurement and measurement systems is equipped with universal measurement technology such as oscilloscopes, spectrum and vector, and logic analyzers, circuit analyzers, PXI, and PXIe-based systems, and other development and simulation tools covering measurement in low-voltage electronic systems. The activities are assigned to the learning outcomes - complex, intelligent electronic systems based on integrating knowledge from the field of electronic circuits, signal processing methods, sensors, and information and communication technologies. Laboratory of industrial systems and microprocessor technology - includes Siemens PLC and control software, converters and sensors, electric drives, PC with Nucleo processor programming tools, and Atmel development boards. Activities are assigned to educational outcomes in the design and implementation of industrial control and automated systems. The SmartIndustryLab laboratory - contains a model of a smart distribution network with elements of renewable sources and electronic loads, class A electricity quality meters, a SCADA system for modeling the distribution system, including photovoltaics and technologies for electromobility. The activities are assigned to the learning outcomes - the design of progressive models of smart networks, advanced methods and tools for computer modeling, and simulations in the distribution of electricity in the environment of the energy mix. List and characteristics of study program laboratories: https://kee.fei.tuke.sk/?page_id=68 http://web.tuke.sk/fei-kte/slovak/laboratories.htm https://kemt.fei.tuke.sk/laboratoria_taxonomia/3/ http://kem.fei.tuke.sk/sk/laboratoria-katedry/
Characteristics of the information provision
Access to study literature and information databases is provided through the TUKE University Library: http://www.lib.tuke.sk/Library/Home/DigitalLibrary. Library services are concentrated in the University Library (UK) of the Technical University in Košice, which includes all activities from searching in the library fund to searching for information in the online catalog and available databases (WoS, Scopus, Springer Link, etc.) to making it available specific documents in printed or electronic form in the UK TUKE fund (the total number of documents is 186,966, of which 64,228 books, 40,046 textbooks, 7,779 anthologies, 6,341 bound periodicals, 7,718 electronic documents, 31,846 final and qualifying theses). UK also provides loan services, consulting services; reference services; digital services; MVS and MKVS services; education and training for writing theses. Access to information technologies is ensured through the Institute of Computing Technology TUKE: https://uvt.tuke.sk/wps/portal/uv/software
E-learning
Access to the Moodle e-learning portal, which is used to support education, is at https://moodle.tuke.sk/moodle/course/index.php?categoryid=129 The rules for working with the Moodle TUKE system are published for students after self-login at https://moodle.tuke.sk/moodle/mod/resource/view.php?id=37854 The applicant for creating a course is obliged to send a request for creating a course to the address moodle@helpdesk.tuke.sk, where he provides the following information:  full name of the course,  a place where the course should be located - (sub)category,  list of TUKE employees, who will have the role of the teacher in the given course,  optional: weekly/topical course format and several weeks/topics. The user must place the video files outside the Moodle system on the TUKE stream server and link them to the Moodle system. Access to the TUKE stream server must be requested and agreed to its terms of use. Instructions on how to register can be found at https://moodle.tuke.sk/moodle/course/view.php?id=1429. Requests for new add-ons/plugins are consulted/suggested via the helpdesk at moodle @helpdesk.tuke.sk A user of the Moodle system can be: - Internal user - a TUKE employee or student assigned a unique login. An internal user becomes a Moodle user after the first login. - External user - person outside TUKE. An external user will be introduced to the Moodle system by the administrator in justified cases. The course teacher requests the creation of an account for an external user by sending a request to the address moodle@helpdesk.tuke.sk
Institution partners
The following partners participate in the provision of educational activities in the study program Industrial Electrical Engineering, 3rd degree, in the form of internships, consultations, provision of specific information, review of papers or participation in commissions for state final exams: Východoslovenská distribučná, a.s. Slovenská elektrizačná prenosová sústava, a.s. Slovenské elektrárne, a.s. ABB s.r.o. Brno Montage Čakovice s.r.o. Prague ABB Slovakia s.r.o. Siemens Gridman, s.r.o. PSM, s.r.o Minebea, s.r.o. Marelli Kechnec Slovakia s.r.o Panasonic Industrial Devices Slovakia, s.r.o. Cannor, s.r.o.. IEEE Sensing, s.r.o. Semicron, s.r.o.

Admission procedures

Required abilities and necessary admission requirement
Admission procedures
Results of the admission process over the last period