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Scalable Tensor Network Simulation for Quantum-Classical Dual Kernel

Quantum Physics 2026-02-03 v1

Abstract

This paper presents an efficient and scalable tensor network framework for quantum kernel circuit simulation, alleviating practical costs associated with increasing qubit counts and data size. The framework enables systematic large-scale evaluation of a linearly mixed quantum-classical dual kernel of up to 784 qubits. Using Fashion-MNIST, the classification performance of the test dataset is compared between a classical kernel, a quantum kernel, and the quantum-classical dual kernel across the feature dimensions from 2 to 784, with a one-to-one mapping between encoded features and qubits. Our result shows that the quantum-classical dual kernel consistently outperforms both single-kernel baselines, remains stable as the dimensionality increases, and mitigates the large-scale degradation observed in the quantum kernel. Analysis of the learned mixing weights indicates that quantum contributions dominate below 128 features, while classical contributions become increasingly important beyond 128, suggesting that the classical kernel provides a stabilizing anchor against concentration effects and hardware noise while preserving quantum gains at lower dimensions.

Keywords

Cite

@article{arxiv.2602.01330,
  title  = {Scalable Tensor Network Simulation for Quantum-Classical Dual Kernel},
  author = {Mei Ian Sam and Tai-Yu Li},
  journal= {arXiv preprint arXiv:2602.01330},
  year   = {2026}
}
R2 v1 2026-07-01T09:30:23.292Z