Cybersecure Distributed Voltage Control of AC Microgrids
| Title | Cybersecure Distributed Voltage Control of AC Microgrids |
| Publication Type | Conference Paper |
| Year of Publication | 2019 |
| Authors | Bidram, Ali, Damodaran, Lakshmisree, Fierro, Rafael |
| Conference Name | 2019 IEEE/IAS 55th Industrial and Commercial Power Systems Technical Conference (I CPS) |
| Date Published | May 2019 |
| Publisher | IEEE |
| ISBN Number | 978-1-5386-7551-9 |
| Keywords | AC microgrids, communication links, Computing Theory, control engineering computing, cyber-attacks, cybersecure distributed voltage control, cybersecurity, cyberthreats, Decentralized control, DERs, distributed control, distributed energy resources, distributed power generation, distributed secondary voltage control, frequency control, graph theory, malicious adversaries, microgrid test system, Microgrids, mobile robot team, mobile robots, multi-robot systems, power system security, Protocols, pubcrawl, Reactive power, reactive power control, resilience, resilience threshold, Resiliency, resilient control approach, resilient flocking, secondary voltage control, security of data, Synchronization, synchronization behavior, utilized control protocols, virtual time-varying communication graph, Voltage control, voltage restoration, weighted mean subsequence reduced algorithm, WMSR algorithm |
| Abstract | In this paper, the cybersecurity of distributed secondary voltage control of AC microgrids is addressed. A resilient approach is proposed to mitigate the negative impacts of cyberthreats on the voltage and reactive power control of Distributed Energy Resources (DERs). The proposed secondary voltage control is inspired by the resilient flocking of a mobile robot team. This approach utilizes a virtual time-varying communication graph in which the quality of the communication links is virtualized and determined based on the synchronization behavior of DERs. The utilized control protocols on DERs ensure that the connectivity of the virtual communication graph is above a specific resilience threshold. Once the resilience threshold is satisfied the Weighted Mean Subsequence Reduced (WMSR) algorithm is applied to satisfy voltage restoration in the presence of malicious adversaries. A typical microgrid test system including 6 DERs is simulated to verify the validity of proposed resilient control approach. |
| URL | https://ieeexplore.ieee.org/document/8733378 |
| DOI | 10.1109/ICPS.2019.8733378 |
| Citation Key | bidram_cybersecure_2019 |
- secondary voltage control
- power system security
- Protocols
- pubcrawl
- Reactive power
- reactive power control
- resilience
- resilience threshold
- Resiliency
- resilient control approach
- resilient flocking
- multi-robot systems
- security of data
- Synchronization
- synchronization behavior
- utilized control protocols
- virtual time-varying communication graph
- Voltage control
- voltage restoration
- weighted mean subsequence reduced algorithm
- WMSR algorithm
- distributed energy resources
- communication links
- Computing Theory
- control engineering computing
- cyber-attacks
- cybersecure distributed voltage control
- Cybersecurity
- cyberthreats
- Decentralized Control
- DERs
- distributed control
- AC microgrids
- distributed power generation
- distributed secondary voltage control
- frequency control
- graph theory
- malicious adversaries
- microgrid test system
- Microgrids
- mobile robot team
- mobile robots