Model Predictive Control of Power Electronic Systems: Methods, Results, and Challenges

Petros Karamanakos; Eyke Liegmann; Tobias Geyer; Ralph Kennel

doi:10.1109/OJIA.2020.3020184

Model Predictive Control of Power Electronic Systems: Methods, Results, and Challenges

Petros Karamanakos, Eyke Liegmann, Tobias Geyer, Ralph Kennel

Lehrstuhl für Hochleistungs-Umrichtersysteme

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

369 Zitate (Scopus)

Abstract

Model predictive control (MPC) has established itself as a promising control methodology in power electronics. This survey paper highlights the most relevant MPC techniques for power electronic systems. These can be classified into two major groups, namely, MPC without modulator, referred to as direct MPC, and MPC with a subsequent modulation stage, known as indirect MPC. Design choices, and parameters that affect the system performance, closed-loop stability, and controller robustness are discussed. Moreover, solvers, and control platforms that can be employed for the real-time implementation of MPC algorithms are presented. Finally, the MPC schemes in question are assessed, among others, in terms of design, and computational complexity, along with their performance, and applicability depending on the power electronic system at hand.

Originalsprache	Englisch
Aufsatznummer	9180048
Seiten (von - bis)	95-114
Seitenumfang	20
Fachzeitschrift	IEEE Open Journal of Industry Applications
Jahrgang	1
DOIs	https://doi.org/10.1109/OJIA.2020.3020184
Publikationsstatus	Veröffentlicht - 2020

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abstract = "Model predictive control (MPC) has established itself as a promising control methodology in power electronics. This survey paper highlights the most relevant MPC techniques for power electronic systems. These can be classified into two major groups, namely, MPC without modulator, referred to as direct MPC, and MPC with a subsequent modulation stage, known as indirect MPC. Design choices, and parameters that affect the system performance, closed-loop stability, and controller robustness are discussed. Moreover, solvers, and control platforms that can be employed for the real-time implementation of MPC algorithms are presented. Finally, the MPC schemes in question are assessed, among others, in terms of design, and computational complexity, along with their performance, and applicability depending on the power electronic system at hand.",

keywords = "Ac drives, direct control, indirect control, integer programming, model predictive control (MPC), modulator, power converters, power electronic systems, quadratic programming",

author = "Petros Karamanakos and Eyke Liegmann and Tobias Geyer and Ralph Kennel",

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AU - Kennel, Ralph

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Model Predictive Control of Power Electronic Systems: Methods, Results, and Challenges

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