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Autores principales: de Valk, Camille, van Nederveen, Milou, Reerink, Koen, van Westering, Werner
Formato: Preprint
Publicado: 2026
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Acceso en línea:https://arxiv.org/abs/2605.03467
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author de Valk, Camille
van Nederveen, Milou
Reerink, Koen
van Westering, Werner
author_facet de Valk, Camille
van Nederveen, Milou
Reerink, Koen
van Westering, Werner
contents Distribution network reconfiguration (DNR) can minimise power losses by identifying the optimal topology of the electricity grid. Determining the minimum loss configuration is NP-hard, and classical optimisation methods struggle to scale to real-world distribution grids. This paper explores the use of gate-based quantum computing to solve DNR for power loss reduction. We formulate DNR as a higher-order unconstrained binary optimisation (HUBO) problem, avoiding the need for auxiliary variables, thereby reducing the required number of qubits. This is applied to a real medium voltage (MV) network operated by Alliander, a Dutch distribution system operator (DSO). For each biconnected component in the network graph, we construct the corresponding HUBO, derive the cost and mixer operators, and determine the number of required logical qubits and rotation gates. These are then mapped to physical qubits and execution time estimates using quantum resource estimation (QRE). The results suggest that the quantum resource requirements depend not only on component size but also on structural characteristics such as connectivity and cyclicity. Overall, the novelty of this work lies in directly framing the optimisation problem as a HUBO, applying it to real-world MV networks, and performing a QRE to assess future feasibility.
format Preprint
id arxiv_https___arxiv_org_abs_2605_03467
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Quantum Resource Estimation for Minimising Energy Grid Losses
de Valk, Camille
van Nederveen, Milou
Reerink, Koen
van Westering, Werner
Quantum Physics
Distribution network reconfiguration (DNR) can minimise power losses by identifying the optimal topology of the electricity grid. Determining the minimum loss configuration is NP-hard, and classical optimisation methods struggle to scale to real-world distribution grids. This paper explores the use of gate-based quantum computing to solve DNR for power loss reduction. We formulate DNR as a higher-order unconstrained binary optimisation (HUBO) problem, avoiding the need for auxiliary variables, thereby reducing the required number of qubits. This is applied to a real medium voltage (MV) network operated by Alliander, a Dutch distribution system operator (DSO). For each biconnected component in the network graph, we construct the corresponding HUBO, derive the cost and mixer operators, and determine the number of required logical qubits and rotation gates. These are then mapped to physical qubits and execution time estimates using quantum resource estimation (QRE). The results suggest that the quantum resource requirements depend not only on component size but also on structural characteristics such as connectivity and cyclicity. Overall, the novelty of this work lies in directly framing the optimisation problem as a HUBO, applying it to real-world MV networks, and performing a QRE to assess future feasibility.
title Quantum Resource Estimation for Minimising Energy Grid Losses
topic Quantum Physics
url https://arxiv.org/abs/2605.03467