Reforming Quantum Microgrid Formation

Chaofan Lin; Peng Zhang; Mikhail A. Bragin; Yacov A. Shamash

doi:10.1109/TPWRS.2025.3527817

Reforming Quantum Microgrid Formation

Chaofan Lin
, Peng Zhang
, Mikhail A. Bragin
, Yacov A. Shamash

Stony Brook University

Stony Brook University
Southern California Edison

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

2 Scopus citations

Abstract

This letter introduces a novel compact and lossless quantum microgrid formation (qMGF) approach to achieve efficient operational optimization of the power system and improvement of resilience. This is achieved through lossless reformulation to ensure that the results are equivalent to those produced by the classical MGF by exploiting graph-theory-empowered quadratic unconstrained binary optimization (QUBO) that avoids the need for redundant encoding of continuous variables. Additionally, the qMGF approach utilizes a compact formulation that requires significantly fewer qubits compared to other quantum methods thereby enabling a high-accuracy and low-complexity deployment of qMGF on near-term quantum computers. Case studies on real quantum processing units (QPUs) empirically demonstrated that qMGF can achieve the same high accuracy as classic results with a significantly reduced number of qubits.

Original language	English
Pages (from-to)	1977-1980
Number of pages	4
Journal	IEEE Transactions on Power Systems
Volume	40
Issue number	2
DOIs	https://doi.org/10.1109/TPWRS.2025.3527817
State	Published - 2025

Keywords

Microgrid formation
graph theory
quadratic unconstrained binary optimization
qubits
resilience

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10.1109/TPWRS.2025.3527817

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title = "Reforming Quantum Microgrid Formation",

abstract = "This letter introduces a novel compact and lossless quantum microgrid formation (qMGF) approach to achieve efficient operational optimization of the power system and improvement of resilience. This is achieved through lossless reformulation to ensure that the results are equivalent to those produced by the classical MGF by exploiting graph-theory-empowered quadratic unconstrained binary optimization (QUBO) that avoids the need for redundant encoding of continuous variables. Additionally, the qMGF approach utilizes a compact formulation that requires significantly fewer qubits compared to other quantum methods thereby enabling a high-accuracy and low-complexity deployment of qMGF on near-term quantum computers. Case studies on real quantum processing units (QPUs) empirically demonstrated that qMGF can achieve the same high accuracy as classic results with a significantly reduced number of qubits.",

keywords = "Microgrid formation, graph theory, quadratic unconstrained binary optimization, qubits, resilience",

author = "Chaofan Lin and Peng Zhang and Bragin, \{Mikhail A.\} and Shamash, \{Yacov A.\}",

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AU - Lin, Chaofan

AU - Zhang, Peng

AU - Bragin, Mikhail A.

AU - Shamash, Yacov A.

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AB - This letter introduces a novel compact and lossless quantum microgrid formation (qMGF) approach to achieve efficient operational optimization of the power system and improvement of resilience. This is achieved through lossless reformulation to ensure that the results are equivalent to those produced by the classical MGF by exploiting graph-theory-empowered quadratic unconstrained binary optimization (QUBO) that avoids the need for redundant encoding of continuous variables. Additionally, the qMGF approach utilizes a compact formulation that requires significantly fewer qubits compared to other quantum methods thereby enabling a high-accuracy and low-complexity deployment of qMGF on near-term quantum computers. Case studies on real quantum processing units (QPUs) empirically demonstrated that qMGF can achieve the same high accuracy as classic results with a significantly reduced number of qubits.

KW - Microgrid formation

KW - graph theory

KW - quadratic unconstrained binary optimization

KW - qubits

KW - resilience

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DO - 10.1109/TPWRS.2025.3527817

M3 - Article

SN - 0885-8950

VL - 40

SP - 1977

EP - 1980

JO - IEEE Transactions on Power Systems

JF - IEEE Transactions on Power Systems

IS - 2

ER -

Reforming Quantum Microgrid Formation

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Keywords

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