English

Quantum-Enhanced Neural Contextual Bandit Algorithms

Machine Learning 2026-01-07 v1 Information Theory math.IT Quantum Physics

Abstract

Stochastic contextual bandits are fundamental for sequential decision-making but pose significant challenges for existing neural network-based algorithms, particularly when scaling to quantum neural networks (QNNs) due to issues such as massive over-parameterization, computational instability, and the barren plateau phenomenon. This paper introduces the Quantum Neural Tangent Kernel-Upper Confidence Bound (QNTK-UCB) algorithm, a novel algorithm that leverages the Quantum Neural Tangent Kernel (QNTK) to address these limitations. By freezing the QNN at a random initialization and utilizing its static QNTK as a kernel for ridge regression, QNTK-UCB bypasses the unstable training dynamics inherent in explicit parameterized quantum circuit training while fully exploiting the unique quantum inductive bias. For a time horizon TT and KK actions, our theoretical analysis reveals a significantly improved parameter scaling of Ω((TK)3)\Omega((TK)^3) for QNTK-UCB, a substantial reduction compared to Ω((TK)8)\Omega((TK)^8) required by classical NeuralUCB algorithms for similar regret guarantees. Empirical evaluations on non-linear synthetic benchmarks and quantum-native variational quantum eigensolver tasks demonstrate QNTK-UCB's superior sample efficiency in low-data regimes. This work highlights how the inherent properties of QNTK provide implicit regularization and a sharper spectral decay, paving the way for achieving ``quantum advantage'' in online learning.

Keywords

Cite

@article{arxiv.2601.02870,
  title  = {Quantum-Enhanced Neural Contextual Bandit Algorithms},
  author = {Yuqi Huang and Vincent Y. F Tan and Sharu Theresa Jose},
  journal= {arXiv preprint arXiv:2601.02870},
  year   = {2026}
}

Comments

30 pages, under review

R2 v1 2026-07-01T08:52:22.338Z