Advanced Course of Power Electronics
BASIC DATA
course listing
A - main register
course code
EEV5050
course title in Estonian
Jõuelektroonika erikursus
course title in English
Advanced Course of Power Electronics
course volume CP
-
ECTS credits
6.00
to be declared
yes
fully online course
not
assessment form
Examination
teaching semester
spring
language of instruction
Estonian
English
Study programmes that contain the course
code of the study programme version
course compulsory
yes
Structural units teaching the course
EE - Department of Electrical Power Engineering and Mechatronics
Timetable link
Version:
VERSION SPECIFIC DATA
course aims in Estonian
1. Tutvustada kaasaegse jõuelektroonika arengusuundi, uusimaid pooljuht komponente, muundurite topoloogiaid ja juhtimismeetodeid erinevates rakendustes.
2. Anda algteadmised jõuelektroonika muundurite ja nende juhtimissüsteemide projekteerimise kohta.
3. Õpetada jõuelektroonika muundurite modelleerimist ja simuleerimist arvutil.
4. Arendada praktilisi ja käelisi oskuseid jõuelektroonika iseseisvaks ehitamiseks.
2. Anda algteadmised jõuelektroonika muundurite ja nende juhtimissüsteemide projekteerimise kohta.
3. Õpetada jõuelektroonika muundurite modelleerimist ja simuleerimist arvutil.
4. Arendada praktilisi ja käelisi oskuseid jõuelektroonika iseseisvaks ehitamiseks.
course aims in English
1. To provide an overview of new semiconductor components, special converter topologies and control methods of the modern power electronics.
2. To give basic design skills of the power electronic converters and their control systems.
3. To teach modelling and simulation methods of power electronic converters.
4. To develop practical skills for building power electronic converters.
2. To give basic design skills of the power electronic converters and their control systems.
3. To teach modelling and simulation methods of power electronic converters.
4. To develop practical skills for building power electronic converters.
learning outcomes in the course in Est.
1. Tunneb kaasaegsete jõuelektroonika muundurite topoloogiaid, nende omadusi ja oskab hinnata nende sobivust eri rakendustesse.
2. Tunneb jõuelektroonika muundurite koostisosi ja oskab nende parameetreid arvutada.
3. Oskab kasutada põhilisi tarkvarapakette muundurite simuleerimiseks ja modelleerimiseks.
4. Tunneb jõuelektroonika muundurite juhtimispõhimõtteid ja põhilisi regulaatorite tüüpe.
5. Tunneb muundurites esinevaid vigu ja oskab neid leida
6. Praktilised kogemused jõuelektroonika muundurite projekteerimiseks ja ehitamiseks.
2. Tunneb jõuelektroonika muundurite koostisosi ja oskab nende parameetreid arvutada.
3. Oskab kasutada põhilisi tarkvarapakette muundurite simuleerimiseks ja modelleerimiseks.
4. Tunneb jõuelektroonika muundurite juhtimispõhimõtteid ja põhilisi regulaatorite tüüpe.
5. Tunneb muundurites esinevaid vigu ja oskab neid leida
6. Praktilised kogemused jõuelektroonika muundurite projekteerimiseks ja ehitamiseks.
learning outcomes in the course in Eng.
A student shall have:
1. A general overview of modern power electronic converter topologies, their properties and applications.
2. Knowledge about components of power electronic converters and ability to calculate their parameters.
3. Skills to use power electronic specific computer software for simulation and modelling.
4. Knowledge of control principles and compensators used in power electronic converters.
5. Knowledge about typical faults in converters and ability to find them.
6. Practical skills to design and build a power electronic converter.
1. A general overview of modern power electronic converter topologies, their properties and applications.
2. Knowledge about components of power electronic converters and ability to calculate their parameters.
3. Skills to use power electronic specific computer software for simulation and modelling.
4. Knowledge of control principles and compensators used in power electronic converters.
5. Knowledge about typical faults in converters and ability to find them.
6. Practical skills to design and build a power electronic converter.
brief description of the course in Estonian
Kaasaegse jõuelektroonika arengusuunad. Uudsed jõuelektroonika pooljuhtkomponendid (SiC ja GaAs transistorid). Jõuelektroonika muundurid taastuvenergeetika rakendustele. Muundurite modelleerimine (Matlab, Mathcadis), simuleerimine (PSIM ja PLECS). Muundurite juhtimispõhimõtted ja stabiilsus kriteeriumid. Häiringute ja vigade analüüs jõuelektroonikas. Reaalse muunduri arvutamine, simuleerimine ja ehitamine laboris.
brief description of the course in English
Development trends of the modern power electronics. Novel semiconductor components (SiC and GaAs devices). Power electronic converters for renewable energy applications. Modelling (Matlab, Mathcad) and simulation (PSIM, PLECS) of converters. Control principles and stability criteria of converters. Analysis of interferences and faults of power electronics. Design, simulation and construction of a real power electronic converter.
type of assessment in Estonian
-
type of assessment in English
-
independent study in Estonian
-
independent study in English
-
study literature
1. M. H. Rashid, „Power Electronics: Circuits, Devices, and Applications“
2. R.W. Erickson, „Fundamentals of Power Electronics“
3. S. Maniktala Switching Power Supplies A to Z
2. R.W. Erickson, „Fundamentals of Power Electronics“
3. S. Maniktala Switching Power Supplies A to Z
study forms and load
daytime study: weekly hours
4.0
session-based study work load (in a semester):
lectures
1.0
lectures
-
practices
3.0
practices
-
exercises
0.0
exercises
-
lecturer in charge
-
LECTURER SYLLABUS INFO
semester of studies
teaching lecturer / unit
language of instruction
Extended syllabus
2025/2026 spring
Indrek Roasto, EE - Department of Electrical Power Engineering and Mechatronics
Estonian