The master programme in electrical engineering is suitable for students with the interest of electrical power systems and electrical energy sources, power electronics and electrical motor drives, and electrical engineering is a fast growing field with a lot of career opportunities.UIT Campus Narvik has a ph.d. education within the field of Engineering Science and Technology
Masterprogrammet innen Elektroteknikk er egnet for studenter med interesse for elkraftsystemer og elektriske energikilder, kraftelektronikk og elektriske motordrifter. Elektroteknikk er et raskt voksende felt med mange karrieremuligheter. UIT Campus Narvik tilbyr doktorgradsutdanning innen ingeniørvitenskap og teknologi.
(Se mer informasjon nedenfor under 'Søkerinformasjon')
Electrical Engineering deals about applied electrical technology. It is a complex and dynamic discipline ranging from microelectronics through electromagnetism to high-power technology, from development of tomorrow's information technology to automation and instrumentation of complex industrial processes. Electronic engineers have for decades revolutionized our ordinary day. The concept "high tech" is largely based on innovations in the field of electrical engineering. Within the range of this discipline, you have the opportunity to learn to master a diverse range of skills.
- Renewable energy
- Stability and reliability in power systems
- Operation, control and economics in power systems
- Power electronics and electric motor drives
- Control theory
The Master program will provide you a solid understanding of areas such as computer engineering, signal processing, control engineering, power electronics, microprocessor technology and programming, mechatronics and electric motor drives and electromagnetism. You will also work in practical, industry-related project, which provides additional opportunity for academic study. Both the projects and the final thesis is usually performed in cooperation with companies. This gives you the unique opportunity to get in contact with a possible future employer.
After completing the study program the candidate has the following learning outcome:
• has basic knowledge about economics and innovation, with special focus on creating an enterprise, developing concepts and protection of rights.
• knows the principles of electric power system and understands the limitations and bottlenecks in such a system. Key topics are renewable energy, stability of power systems and operation and control of power systems.
• has a thorough knowledge of electrical machines, their dynamics and choice of suitable converter types for motor drives. The candidate also knows about available measurement sensors and how these could be integrated in an advanced control system.
• has basic knowledge of computer architecture and programming.
• can use linear algebra and numerical methods as mathematical tools for analyzing physical processes and technical solutions.
• can combine power electronics, control engineering and electrical systems into advanced electric motor drives.
• can perform basic simulations and analyzes of power systems, in regards to load flow, stability, operating conditions or economic considerations.
• can use computers, microcontrollers or other types of microelectronics in order to control and monitor mechatronic systems.
• completes the study program through performing a larger diploma work of a six-month duration.
• gains insight into new and innovative technologies and will be able to put these into a society perspective.
• gains insight into various aspects of future network systems, energy solutions and climate challenges.
• is able to combine energy systems with signal transfer and ICT solutions in an overall system with high flexibility.
You can work in development, construction, research, environmental surveillance, data technology, electrical supply and instrumentation. Employers are often in the process industry and the power sector.
With a growing focus on the development of sustainable and renewable energy production, electric energy will play a key role in many new energy-intensive areas of our society. We see it in transport, on land, sea and in the air as an exciting development area. The electrical engineer will play a central role in the renewable energy community of the future.
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The basis of admission is
a relevant undergraduate Bachelor degree in Engineering programme in power electronics and electrical machines. Basic knowledge in power systems is also an advantage.
In addition, the following requirements must be met:
- minimum 25 credits in mathematics, 5 credits in statistics and 7,5 ects i physics on a higher level is required. (Some of the courses in the bachelor engineering programme may have a certain amount of physics included and can be accepted*.)
In most bachelor's degrees in engineering, you must expect to take some elective science subjects to qualify for the master's degree. At UiT you can take TEK-2800 Mathematics 3 (5 ects) and TEK-2801 Physics 2 (5 ects) to meet the requirement of mathematics and physics.
*)Courses at UiT with content of acceptable physics: See attachements to the Studyplan for more information.
If the bachelor's degree has been taken at another university, confirmed documentation must be attached of which courses and the number of credits in physics are included.
Applicants from Norway or Nordic countries:
- The application deadline for Norwegian and other Nordic applicants is April 15th for admission to the autumn semester
Online application is via Søknadsweb, study code 4601
Applicants from outside the Nordic countries:
- The application deadline for applicants outside the Nordic countries is December 1st for admission to the autumn semester.
Online application, study code 9006
Are you an international applicant? How to apply
For more details on admission requirements (GSU-list etc.):
In Week 33 a two-days refresher course in linear algebra is offered. In this course, central concepts and methods from previous linear algebra courses will be repeated. Experiences from previous years are that students who participate in this refresher course benefit greatly from this in SMN6190 Linear Algebra II.
All teaching on this program takes place in English.
Most of the courses are based on lectures, self-study and exercises, individually or in groups. Exercises can be either voluntary or mandatory. There are several laboratory exercises included in projects. Please refer to the individual course descriptions for additional information.
To some extent there are also mandatory projects to be done. These are carried out by groups of students working out a final project report which is to be presented to a teacher, an examiner or fellow students. Topics for such a project may be based on laboratory experiments, relevant business issues or similar. Some courses are entirely based on projects with some guidance from teachers.
The final master thesis may be performed in close cooperation with relevant industry partners and/or on basis of existing R&D projects. The student work is normally done individually. During the work period there will be presentations and milestone status meetings.
Form of assessment
Throughout the program, various forms of evaluation are used for the different subjects, depending on the preferences of the teachers. In most cases a written exam provides the main evaluation. In addition to the written exams, mandatory assignments or projects (individually or in groups) will often be included in the final evaluation.
Portfolio assessment is used for some subjects, while others are evaluated on basis of the final report and maybe also a presentation. The master thesis is solely evaluated on the basis of a written final report. More information about the different courses is to be found in the course descriptions.
Mandatory safety training in health, security and environment (HSE)
All students must complete mandatory safety training before they are allowed access and given permission to work in laboratories, workshops and the like. This also goes for participation in fieldwork/research cruises and similar. Please contact your immediate supervisor for list of mandatory courses.
The program qualifies students to take a PhD, and campus Narvik can offer such an education in collaboration with other universities in Norway and Sweden. PhD students carry out their research work in the research group Electromechanical Systems.
It is possible to study parts of the master program at other universities. An individual plan must in this case be made in accordance with the program leader.
Har du spørsmål om studiet?
Send mail til firstname.lastname@example.org
15. april er søknadsfristen for søkere med norsk/nordisk utdanningsbakgrunn - søknadskode 4601
Til dette programmet ønskes både norske- og engelskspråklige studenter.
Språk: Forelesningene gis på engelsk. Til eksamen er det mulig å søke om å få oppgavesett og/eller besvare eksamen på et annet språk.
Opptakskrav Elektroteknikk, sivilingeniør - master:
Bachelor i ingeniørfag i kraftelektronikk og elektriske maskiner. Grunnleggende kunnskap i kraftsystemer er også en fordel. I tillegg må følgende krav være oppfylt:
Det kreves minimum
- 25 studiepoeng i matematikk,
- 5 studiepoeng i statistikk
- 7,5 fag i fysikk på høyere nivå. (Noen av kursene i bachelor ingeniørprogrammet kan ha en viss mengde fysikk inkludert som kan godkjennes.) Under fanen Studieplan finner du hvilke emner dette gjelder.
I de fleste bachelorgrader i ingeniørfag må du forvente å ta noen valgfag for å kvalifisere for mastergraden. På UiT i Narvik kan du ta TEK-2800 Matematikk 3 (5 sp) og TEK-2801 Fysikk 2 (5 sp) for å oppfylle kravet til matematikk og fysikk.
Spørsmål om opptak kan sendes til: email@example.com
The candidate will be awarded the right to use the Norwegian professional title sivilingeniør. This right is legally protected in Norway.
Du har rett til å bruke den beskyttede tittelen sivilingeniør etter endt studium. Det vil fremgå av vitnemålet.