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Bibliographic Details
Main Author: Borneman, Sean
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.06410
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author Borneman, Sean
author_facet Borneman, Sean
contents I present a novel use of quantum annealing to solve the Set Splitting Problem using (QUBO) problem formulation. The contribution of the work is in formulating penalty functions that ensure the ground state of the QUBO Hamiltonian corresponds to valid solutions that split the input subsets. This approach scales linearly in terms of the number of logical qubits relative to problem size. Empirical tests of the proposed solution show convergence to globally optimal solutions, with high accuracy rates over repeated trials. Hardware limitations of current quantum annealers lead to an exponential rise in required physical qubits, versus the theoretical linear increase, although this can improve with future developments. Further work is needed to enhance formulation robustness, reduce qubit requirements for embedded problems, and to conduct more extensive bench-marking. Quantum solutions to the Set-Splitting problem lead to reduced time complexity versus classical solutions, and may accelerate research in biology, cybersecurity, and other domains.
format Preprint
id arxiv_https___arxiv_org_abs_2508_06410
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum Annealing for the Set Splitting Problem
Borneman, Sean
Quantum Physics
I present a novel use of quantum annealing to solve the Set Splitting Problem using (QUBO) problem formulation. The contribution of the work is in formulating penalty functions that ensure the ground state of the QUBO Hamiltonian corresponds to valid solutions that split the input subsets. This approach scales linearly in terms of the number of logical qubits relative to problem size. Empirical tests of the proposed solution show convergence to globally optimal solutions, with high accuracy rates over repeated trials. Hardware limitations of current quantum annealers lead to an exponential rise in required physical qubits, versus the theoretical linear increase, although this can improve with future developments. Further work is needed to enhance formulation robustness, reduce qubit requirements for embedded problems, and to conduct more extensive bench-marking. Quantum solutions to the Set-Splitting problem lead to reduced time complexity versus classical solutions, and may accelerate research in biology, cybersecurity, and other domains.
title Quantum Annealing for the Set Splitting Problem
topic Quantum Physics
url https://arxiv.org/abs/2508.06410