Blockchain-Enabled Cyber-Secure Microgrid Control Using Consensus Algorithm
This paper proposes a distributed control method based on a consensus algorithm for distributed energy resources (DERs) using blockchain as a secure communication medium for cyber resilience. Each DER communicates with a local blockchain server that is maintained by the distributed ledger technology to allow for securely sharing local measurements among neighboring assets to achieve the global control objectives, i.e., voltage and frequency regulation as well as accurate power sharing among the DERs, including collective grid-forming capability. To prove that the distributed control can retain system stability under a blockchain-induced variable communication delay, Lyapunov function-based stability analysis is carried out. This paper demonstrates the concept on an 11-bus test case developed in MATLAB Simulink, which has been modified from the IEEE 9-bus test case, to study dynamic operations of the five inverter-based DERs working with a blockchain-induced variable delay. The results validate the superior performance of the proposed control method, compared to heavily compromised operations of the other test cases without the security measure, affected by heavy communication delays and communication interruptions.
Citation Formats
TY - DATA
AB - This paper proposes a distributed control method based on a consensus algorithm for distributed energy resources (DERs) using blockchain as a secure communication medium for cyber resilience. Each DER communicates with a local blockchain server that is maintained by the distributed ledger technology to allow for securely sharing local measurements among neighboring assets to achieve the global control objectives, i.e., voltage and frequency regulation as well as accurate power sharing among the DERs, including collective grid-forming capability. To prove that the distributed control can retain system stability under a blockchain-induced variable communication delay, Lyapunov function-based stability analysis is carried out. This paper demonstrates the concept on an 11-bus test case developed in MATLAB Simulink, which has been modified from the IEEE 9-bus test case, to study dynamic operations of the five inverter-based DERs working with a blockchain-induced variable delay. The results validate the superior performance of the proposed control method, compared to heavily compromised operations of the other test cases without the security measure, affected by heavy communication delays and communication interruptions.
AU - Mahmud, Rasel
A2 - Seo, Gab-Su
DB - C-MIX - Community Microgrid Information Exchange
DP - Open EI | National Laboratory of the Rockies
DO - 10.1109/COMPEL52922.2021.9645973
KW - Battery energy storage
KW - Solar
KW - Photovoltaics
KW - PV
KW - Diesel generators
KW - Other liquid-fuel generators
KW - Wind energy
KW - Cybersecurity
KW - Power plant controls
KW - SCADA
KW - Case studies
KW - Performance
KW - Maintenance and operations
KW - Operations
KW - Maintenance
KW - Commissioning
LA - English
DA - 2021/01/01
PY - 2021
PB - NLR
T1 - Blockchain-Enabled Cyber-Secure Microgrid Control Using Consensus Algorithm
UR - https://doi.org/10.1109/COMPEL52922.2021.9645973
ER -
Mahmud, Rasel, and Gab-Su Seo. Blockchain-Enabled Cyber-Secure Microgrid Control Using Consensus Algorithm. NLR, 1 January, 2021, C-MIX - Community Microgrid Information Exchange. https://doi.org/10.1109/COMPEL52922.2021.9645973.
Mahmud, R., & Seo, G. (2021). Blockchain-Enabled Cyber-Secure Microgrid Control Using Consensus Algorithm. [Data set]. C-MIX - Community Microgrid Information Exchange. NLR. https://doi.org/10.1109/COMPEL52922.2021.9645973
Mahmud, Rasel and Gab-Su Seo. Blockchain-Enabled Cyber-Secure Microgrid Control Using Consensus Algorithm. NLR, January, 1, 2021. Distributed by C-MIX - Community Microgrid Information Exchange. https://doi.org/10.1109/COMPEL52922.2021.9645973
@misc{CMIX_Dataset_43,
title = {Blockchain-Enabled Cyber-Secure Microgrid Control Using Consensus Algorithm},
author = {Mahmud, Rasel and Seo, Gab-Su },
abstractNote = {This paper proposes a distributed control method based on a consensus algorithm for distributed energy resources (DERs) using blockchain as a secure communication medium for cyber resilience. Each DER communicates with a local blockchain server that is maintained by the distributed ledger technology to allow for securely sharing local measurements among neighboring assets to achieve the global control objectives, i.e., voltage and frequency regulation as well as accurate power sharing among the DERs, including collective grid-forming capability. To prove that the distributed control can retain system stability under a blockchain-induced variable communication delay, Lyapunov function-based stability analysis is carried out. This paper demonstrates the concept on an 11-bus test case developed in MATLAB Simulink, which has been modified from the IEEE 9-bus test case, to study dynamic operations of the five inverter-based DERs working with a blockchain-induced variable delay. The results validate the superior performance of the proposed control method, compared to heavily compromised operations of the other test cases without the security measure, affected by heavy communication delays and communication interruptions.},
url = {https://cmix.openei.org/submissions/43},
year = {2021},
howpublished = {C-MIX - Community Microgrid Information Exchange, NLR, https://doi.org/10.1109/COMPEL52922.2021.9645973},
note = {Accessed: 2026-06-14},
doi = {10.1109/COMPEL52922.2021.9645973}
}
https://dx.doi.org/10.1109/COMPEL52922.2021.9645973
Details
Data from Jan 1, 2021
Last updated Mar 30, 2026
Submitted Jun 2, 2026
Organization
NLR
Contact
Gab-Su Seo
Authors
