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i-QLS: Quantum-supported Algorithm for Least Squares Optimization in Non-Linear Regression

Quantum Physics 2025-10-10 v1 Discrete Mathematics

Abstract

We propose an iterative quantum-assisted least squares (i-QLS) optimization method that leverages quantum annealing to overcome the scalability and precision limitations of prior quantum least squares approaches. Unlike traditional QUBO-based formulations, which suffer from a qubit overhead due to fixed discretization, our approach refines the solution space iteratively, enabling exponential convergence while maintaining a constant qubit requirement per iteration. This iterative refinement transforms the problem into an anytime algorithm, allowing for flexible computational trade-offs. Furthermore, we extend our framework beyond linear regression to non-linear function approximation via spline-based modeling, demonstrating its adaptability to complex regression tasks. We empirically validate i-QLS on the D-Wave quantum annealer, showing that our method efficiently scales to high-dimensional problems, achieving competitive accuracy with classical solvers while outperforming prior quantum approaches. Experiments confirm that i-QLS enables near-term quantum hardware to perform regression tasks with improved precision and scalability, paving the way for practical quantum-assisted machine learning applications.

Keywords

Cite

@article{arxiv.2505.02788,
  title  = {i-QLS: Quantum-supported Algorithm for Least Squares Optimization in Non-Linear Regression},
  author = {Supreeth Mysore Venkatesh and Antonio Macaluso and Diego Arenas and Matthias Klusch and Andreas Dengel},
  journal= {arXiv preprint arXiv:2505.02788},
  year   = {2025}
}

Comments

11 pages, 4 figures

R2 v1 2026-06-28T23:21:43.324Z