Deadbeat Current Control in Grid-Connected Inverters: A Comprehensive Discussion

Discrete-time dynamic systems demonstrate quite exciting possibilities from the perspective of control as compared with the continuous-time counterpart. Interesting properties of discrete-time dynamic systems include the possibility to algebraically determine previously unknown system parameters by...

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Published inIEEE access Vol. 10; pp. 3990 - 4014
Main Authors Elhassan, Garba, Zulkifli, Shamsul Aizam, Iliya, Solomon Zakwoi, Bevrani, Hassan, Kabir, Momoh, Jackson, Ronald, Khan, Mubashir Hayat, Ahmed, Mohammed
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2022
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Current control
Current measurement
Deadbeat control
Discrete time systems
Dynamical systems
grid-connected inverter
Harmonic analysis
Inverters
Mathematical analysis
Power harmonic filters
Power system stability
renewable energy sources
Settling
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Summary:Discrete-time dynamic systems demonstrate quite exciting possibilities from the perspective of control as compared with the continuous-time counterpart. Interesting properties of discrete-time dynamic systems include the possibility to algebraically determine previously unknown system parameters by simply measuring the present inputs and outputs of the system. Additionally, achieving a finite settling time with zero steady-state error is only achievable in discrete-time dynamic systems. Deadbeat current control (DBCC) has been used to achieve a finite settling time, especially in grid-connected inverter applications. However, there is no comprehensive study on reviewing or evaluating existing control approaches, to the authors' best knowledge. This paper systematically examined the existing methods by paying attention to four key research issues: 1) research evidence indicating the adoption of DBCC in grid-connected inverter applications (GCIAs), 2) the types of deadbeat control approaches adopted in GCIAs, 3) the best approach in terms of stability especially regarding grid-impedance variation, and 4) the barriers that might prevent the wide adoption of DBCC in GCIAs. Finally, this paper presents a hypothesis based on the simulated results on which approach is superior at present to give readers a direction for further research classification on deadbeat control.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2021.3138789