open access publication

Article, 2024

A hybrid quantum–classical algorithm for mixed-integer optimization in power systems

Electric Power Systems Research, ISSN 1873-2046, 0378-7796, Volume 235, Page 110835, 10.1016/j.epsr.2024.110835

Contributors

Ellinas, Petros 0000-0002-5469-5667 (Corresponding author) [1] Chevalier, Samuel C 0000-0003-2426-1857 [1] Chatzivasileiadis, Spyros 0000-0003-4698-8694 [1]

Affiliations

  1. [1] Technical University of Denmark
    2. [NORA names: DTU Technical University of Denmark; University; Denmark; Europe, EU; Nordic; OECD]

Abstract

Mixed Integer Linear Programming (MILP) can be considered the backbone of the modern power system optimization process, with a large application spectrum, from Unit Commitment and Optimal Transmission Switching to verifying Neural Networks for power system applications. The main issue of these formulations is the computational complexity of the solution algorithms, as they are considered NP-Hard problems. Quantum computing has been tested as a potential solution towards reducing the computational burden imposed by these problems, providing promising results, motivating the can be used to speedup the solution of MILPs. In this work, we present a general framework for solving power system optimization problems with a Quantum Computer (QC), which leverages mathematical tools and QCs’ sampling ability to provide accelerated solutions. Our guiding applications are the optimal transmission switching and the verification of neural networks trained to solve a DC Optimal Power Flow. Specifically, using an accelerated version of Benders Decomposition , we split a given MILP into an Integer Master Problem and a linear Subproblem and solve it through a hybrid “quantum–classical” approach, getting the best of both worlds. We provide 2 use cases, and benchmark the developed framework against other classical and hybrid methodologies, to demonstrate the opportunities and challenges of hybrid quantum–classical algorithms for power system mixed integer optimization problems.

Keywords

Benders decomposition, DC optimal power flow, Mixed Integer Linear Programming, NP-hard, NP-hard problem, Neural, ability, accelerated version, acceleration solution, algorithm, application spectrum, applications, approach, backbone, burden, cases, challenges, commitment, complex, computational burden, computational complexity, computer, decomposition, flow, formulation, framework, hybrid, hybrid quantum-classical algorithms, integer, integer linear programming, integer master problem, integer optimization problem, issues, linear programming, master problem, mathematical tools, methodology, mixed integer optimization problem, mixed-integer optimization, network, neural network, opportunities, optimal power flow, optimal transmission switching, optimization, optimization problem, optimization process, potential solutions, power, power flow, power system, power system applications, problem, process, program, quantum, quantum computation, quantum-classical algorithm, quantum-classical approach, results, sampling ability, solution, solution algorithm, spectra, subproblems, switching, system, system applications, system optimization process, tools, transmission switching, unit commitment, units, verification, verification of neural networks, versions of Benders decomposition, world

Funders

  • European Research Council

Data Provider: Digital Science

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