Scalable Robust Voltage Control of DC Microgrids With Uncertain Constant Power Loads

Scalable Robust Voltage Control of DC Microgrids With Uncertain Constant Power Loads

Constant power loads (CPLs) impose instability issues in DC microgrids due to their negative impedance characteristics. This paper studies the problem of voltage control design of DC microgrids with CPLs. It is assumed that the power of CPLs is uncertain and belongs to a given interval leading to an...

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Veröffentlicht in:IEEE transactions on power systems 2020-01, Vol.35 (1), p.508-515
Hauptverfasser: Sadabadi, Mahdieh S., Shafiee, Qobad
Format: Artikel
Sprache:eng
Schlagworte:
Computer simulation
Constant power load (CPL)
Control theory
DC microgrids
Distributed generation
Electric power grids
Feedforward control
Linear matrix inequalities
linear matrix inequality (LMI)
Load modeling
load uncertainty
Mathematical analysis
Mathematical model
Microgrids
polytopic systems
Power system dynamics
Robust control
robust voltage control
scalable control design
Stability analysis
Uncertainty
Voltage control
Voltage controllers
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Zusammenfassung:Constant power loads (CPLs) impose instability issues in DC microgrids due to their negative impedance characteristics. This paper studies the problem of voltage control design of DC microgrids with CPLs. It is assumed that the power of CPLs is uncertain and belongs to a given interval leading to an infinite number of equilibrium points of the system. We develop a polytope model for DC microgrids with uncertain CPLs. Using this model, a robust two-degree-of-freedom feedback-feedforward voltage control framework is then proposed. The voltage controller is obtained by a solution of a set of linear matrix inequalities. The voltage control design strategy for each distributed generation (DG) unit is scalable and independent of the other DGs. The effectiveness of the proposed control approach is evaluated through simulation studies in MATLAB/SimPowerSystems toolbox.
ISSN:0885-8950
1558-0679
DOI:10.1109/TPWRS.2019.2928512