ADVANCED ELEMENTS OF ELECTRONIC POWER SYSTEMS
cod. 1009162

Academic year 2023/24
1° year of course - Second semester
Professors
Academic discipline
Convertitori, macchine e azionamenti elettrici (ING-IND/32)
Field
A scelta dello studente
Type of training activity
Related/supplementary
48 hours
of face-to-face activities
6 credits
hub: PARMA
course unit
in ENGLISH

Learning objectives

Apply model-based techniques to the design of complex electronics-based power systems;
Master advanced techniques for modeling and implementing control systems applied to energy management;
Forecast reliability of electronic power systems and make choices to maximize lifetime by design;
Devise diagnostic and prognostic algorithms for power electronics;
Know and design gate drivers and sensors for power electronics devices.

Prerequisites

Suggested prerequisites are: programming fundamentals, embedded architectures, electronic devices, control theory, basic power converters.

Course unit content

Model-based design of power converters and systems;
Numerical analysis and programming tools;
V-model and MIL, SIL, PIL and HIL validation;
Version control systems;
Design-for-reliability in power electronics;
Gate drivers for electronic power devices;
Faults in power electronics, diagnosis, prognostics;
Advanced sensors for power system control and reliability.

Full programme

1. Model-based design of power converters and systems (2 h)
2. System partitioning and abstraction levels (2 h)
3. V-model, automatic test-benches and documentation (2 h)
4. Mil, sil, pil and hil validation and tools (2 h)
5. The building and programming system (2 h)
6 version control systems: basic principles and comparative analysis (2 h)
7. Numerical analysis: real-time computation (2 h)
8. Numerical analysis: solvers (2 h)
9 numerical analysis: optimizers (2 h)
10. Numerical analysis: system modeling and identification [tutorial] (2 h)
11. High-level modeling of power converters (2 h)
12. Control modeling for power converters [tutorial] (2 h)
13. Design-for-reliability in power electronics (2 h)
14. Lifetime models for power system components (2 h)
15. Simulation workflow for reliability prediction [tutorial] (2 h)
16. Gate drivers for power electronics devices (2 h)
17. Active gate drivers for wide bandgap devices (2 h)
18. Active thermal control of power electronics (2 h)
19. Faults in power electronics (2 h)
20. Power electronics diagnostics (2 h)
21. Prognostics algorithms (2 h)
22. Advanced sensors for power system control and reliability (2 h)
23. Logging and counting techniques (2 h)
24. Design of advanced sensing and driving circuits for power electronics [tutorial] (2 h)

Bibliography

Orłowska-Kowalska Et Al., "Advanced And Intelligent Control In Power Electronics And Drives", Springer, 2014.
Lee Et Al., "Reliability Improvement Technology For Power Converters", Springer, 2017.
Iannuzzo F (ed.), Modern Power Electronic Devices: Physics, Applications, and Reliability. Stevenage, UK: IET;
2020.
Chung Et Al., "Reliability Of Power Electronic Converter Systems", Iet, 2015.

Teaching methods

Class lectures and tutorials using relevant software tools.

Assessment methods and criteria

Oral exam (mandatory) and course project (optional) on a relevant topic connected to the proposed contents.

Other information

In the eventuality of restrictions to gatherings, classes will be given online, recorded via Teams and published via Elly.

2030 agenda goals for sustainable development

7. Affordable and clean energy
12. Responsible consumption and production
13. Climate action