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Hauptverfasser: Castro, Erick R., Martins, Eldues O., Sarthour, Roberto S., Souza, Alexandre M., Oliveira, Ivan S.
Format: Preprint
Veröffentlicht: 2023
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2309.09933
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author Castro, Erick R.
Martins, Eldues O.
Sarthour, Roberto S.
Souza, Alexandre M.
Oliveira, Ivan S.
author_facet Castro, Erick R.
Martins, Eldues O.
Sarthour, Roberto S.
Souza, Alexandre M.
Oliveira, Ivan S.
contents Recent advancements in quantum computing and quantum-inspired algorithms have sparked renewed interest in binary optimization. These hardware and software innovations promise to revolutionize solution times for complex problems. In this work, we propose a novel method for solving linear systems. Our approach leverages binary optimization, making it particularly well-suited for problems with large condition numbers. We transform the linear system into a binary optimization problem, drawing inspiration from the geometry of the original problem and resembling the conjugate gradient method. This approach employs conjugate directions that significantly accelerate the algorithm's convergence rate. Furthermore, we demonstrate that by leveraging partial knowledge of the problem's intrinsic geometry, we can decompose the original problem into smaller, independent sub-problems. These sub-problems can be efficiently tackled using either quantum or classical solvers. While determining the problem's geometry introduces some additional computational cost, this investment is outweighed by the substantial performance gains compared to existing methods.
format Preprint
id arxiv_https___arxiv_org_abs_2309_09933
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Improving the convergence of an iterative algorithm for solving arbitrary linear equation systems using classical or quantum binary optimization
Castro, Erick R.
Martins, Eldues O.
Sarthour, Roberto S.
Souza, Alexandre M.
Oliveira, Ivan S.
Quantum Physics
Computational Physics
Recent advancements in quantum computing and quantum-inspired algorithms have sparked renewed interest in binary optimization. These hardware and software innovations promise to revolutionize solution times for complex problems. In this work, we propose a novel method for solving linear systems. Our approach leverages binary optimization, making it particularly well-suited for problems with large condition numbers. We transform the linear system into a binary optimization problem, drawing inspiration from the geometry of the original problem and resembling the conjugate gradient method. This approach employs conjugate directions that significantly accelerate the algorithm's convergence rate. Furthermore, we demonstrate that by leveraging partial knowledge of the problem's intrinsic geometry, we can decompose the original problem into smaller, independent sub-problems. These sub-problems can be efficiently tackled using either quantum or classical solvers. While determining the problem's geometry introduces some additional computational cost, this investment is outweighed by the substantial performance gains compared to existing methods.
title Improving the convergence of an iterative algorithm for solving arbitrary linear equation systems using classical or quantum binary optimization
topic Quantum Physics
Computational Physics
url https://arxiv.org/abs/2309.09933