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On Quantum Perceptron Learning via Quantum Search

Quantum Physics 2025-03-24 v1 Machine Learning Machine Learning

Abstract

With the growing interest in quantum machine learning, the perceptron -- a fundamental building block in traditional machine learning -- has emerged as a valuable model for exploring quantum advantages. Two quantum perceptron algorithms based on Grover's search, were developed in arXiv:1602.04799 to accelerate training and improve statistical efficiency in perceptron learning. This paper points out and corrects a mistake in the proof of Theorem 2 in arXiv:1602.04799. Specifically, we show that the probability of sampling from a normal distribution for a DD-dimensional hyperplane that perfectly classifies the data scales as Ω(γD)\Omega(\gamma^{D}) instead of Θ(γ)\Theta({\gamma}), where γ\gamma is the margin. We then revisit two well-established linear programming algorithms -- the ellipsoid method and the cutting plane random walk algorithm -- in the context of perceptron learning, and show how quantum search algorithms can be leveraged to enhance the overall complexity. Specifically, both algorithms gain a sub-linear speed-up O(N)O(\sqrt{N}) in the number of data points NN as a result of Grover's algorithm and an additional O(D1.5)O(D^{1.5}) speed-up is possible for cutting plane random walk algorithm employing quantum walk search.

Keywords

Cite

@article{arxiv.2503.17308,
  title  = {On Quantum Perceptron Learning via Quantum Search},
  author = {Xiaoyu Sun and Mathieu Roget and Giuseppe Di Molfetta and Hachem Kadri},
  journal= {arXiv preprint arXiv:2503.17308},
  year   = {2025}
}
R2 v1 2026-06-28T22:30:02.278Z