Multilayer event‐based distributed control system for DC microgrids with non‐uniform delays and directional communication

The secondary control layer of microgrids is often modelled as a multi‐agent distributed system, coordinated based on consensus protocols. Convergence time of consensus algorithm significantly affects transient stability of microgrids, due to changes in communication topology, switching of distribut...

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Bibliographic Details
Published in:IET generation, transmission & distribution transmission & distribution, 2022-01, Vol.16 (2), p.267-281
Main Authors: Alavi, Seyed Amir, Rahimian, Ardavan, Mehran, Kamyar, Vahidinasab, Vahid
Format: Article
Language:English
Subjects:
Combinatorial mathematics
Communication network design, planning and routing
Optimisation techniques
Protocols
Signal processing and detection
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Summary:The secondary control layer of microgrids is often modelled as a multi‐agent distributed system, coordinated based on consensus protocols. Convergence time of consensus algorithm significantly affects transient stability of microgrids, due to changes in communication topology, switching of distributed generations (DGs), and uncertainty of intermittent energy sources. To minimise convergence time in consensus protocol, this work proposes a multilayer event‐based consensus control framework, which is resilient to communication delays and supports plug‐and‐play (P&P) addition or removal of DGs in DC microgrids of cellular energy systems. A novel bi‐layer optimisation algorithm minimises convergence time by selecting an optimal communication topology graph and then adjusts controllers' parameters. Average consensus is achieved among distributed controllers using an event‐based consensus protocol, considering non‐uniform delays between agents. A realisation method has also been introduced using the directional beamforming technique for topology assignment algorithm based on modern telecommunication technologies. Provided feasibility case study has been implemented on a real‐time hardware‐in‐the‐loop (HIL) experimental testbed, to validate the performance of the proposed framework for key purposes of voltage stabilisation and balanced power‐sharing in DC microgrids.
ISSN:1751-8687
1751-8695
DOI:10.1049/gtd2.12284