Passivation of Clustered DC Microgrids With Non-Monotone Loads

Albertus Johannes Malan; Joel Ferguson; Michele Cucuzzella; Jacquelien M.A. Scherpen; Soren Hohmann

doi:10.1109/TCST.2025.3537861

Passivation of Clustered DC Microgrids With Non-Monotone Loads

Albertus Johannes Malan^*, Joel Ferguson, Michele Cucuzzella, Jacquelien M.A. Scherpen, Soren Hohmann

^*Corresponding author for this work

Discrete Technology and Production Automation

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

In this article, we consider the problem of voltage stability in dc networks containing uncertain loads with non-monotone incremental impedances and where the steady-state power availability is restricted to a subset of the buses in the network. We propose controllers for powered buses that guarantee voltage regulation and output strictly equilibrium independent passivity (OS-EIP) of the controlled buses, while buses without power are equipped with controllers that dampen their transient behavior. The OS-EIP of a cluster containing both bus types is verified through a linear matrix inequality (LMI) condition, and the asymptotic stability of the overall microgrid with uncertain, non-monotone loads is ensured by interconnecting the OS-EIP clusters. By further using singular perturbation theory, we show that the OS-EIP property of the clusters is robust against certain network parameter and topology changes.

Original language	English
Pages (from-to)	1069-1084
Number of pages	16
Journal	IEEE Transactions on Control Systems Technology
Volume	33
Issue number	3
Early online date	2025
DOIs	https://doi.org/10.1109/TCST.2025.3537861
Publication status	Published - May-2025

Keywords

DC distribution systems
decentralized control
microgrids
power system stability
voltage control

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title = "Passivation of Clustered DC Microgrids With Non-Monotone Loads",

abstract = "In this article, we consider the problem of voltage stability in dc networks containing uncertain loads with non-monotone incremental impedances and where the steady-state power availability is restricted to a subset of the buses in the network. We propose controllers for powered buses that guarantee voltage regulation and output strictly equilibrium independent passivity (OS-EIP) of the controlled buses, while buses without power are equipped with controllers that dampen their transient behavior. The OS-EIP of a cluster containing both bus types is verified through a linear matrix inequality (LMI) condition, and the asymptotic stability of the overall microgrid with uncertain, non-monotone loads is ensured by interconnecting the OS-EIP clusters. By further using singular perturbation theory, we show that the OS-EIP property of the clusters is robust against certain network parameter and topology changes.",

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AU - Hohmann, Soren

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N2 - In this article, we consider the problem of voltage stability in dc networks containing uncertain loads with non-monotone incremental impedances and where the steady-state power availability is restricted to a subset of the buses in the network. We propose controllers for powered buses that guarantee voltage regulation and output strictly equilibrium independent passivity (OS-EIP) of the controlled buses, while buses without power are equipped with controllers that dampen their transient behavior. The OS-EIP of a cluster containing both bus types is verified through a linear matrix inequality (LMI) condition, and the asymptotic stability of the overall microgrid with uncertain, non-monotone loads is ensured by interconnecting the OS-EIP clusters. By further using singular perturbation theory, we show that the OS-EIP property of the clusters is robust against certain network parameter and topology changes.

AB - In this article, we consider the problem of voltage stability in dc networks containing uncertain loads with non-monotone incremental impedances and where the steady-state power availability is restricted to a subset of the buses in the network. We propose controllers for powered buses that guarantee voltage regulation and output strictly equilibrium independent passivity (OS-EIP) of the controlled buses, while buses without power are equipped with controllers that dampen their transient behavior. The OS-EIP of a cluster containing both bus types is verified through a linear matrix inequality (LMI) condition, and the asymptotic stability of the overall microgrid with uncertain, non-monotone loads is ensured by interconnecting the OS-EIP clusters. By further using singular perturbation theory, we show that the OS-EIP property of the clusters is robust against certain network parameter and topology changes.

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KW - decentralized control

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KW - voltage control

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Passivation of Clustered DC Microgrids With Non-Monotone Loads

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