English

PolyQROM: Orthogonal-Polynomial-Based Quantum Reduced-Order Model for Flow Field Analysis

Quantum Physics 2025-05-01 v1

Abstract

Quantum computing promises exponential acceleration for fluid flow simulations, yet the measurement overhead required to extract flow features from quantum-encoded flow field data fundamentally undermines this advantage--a critical challenge termed the ``output problem''. To address this, we propose an orthogonal-polynomial-based quantum reduced-order model (PolyQROM) that integrates orthogonal polynomial basis transformations with variational quantum circuits (VQCs). PolyQROM employs optimized polynomial-based quantum operations to compress flow field data into low-dimensional representations while preserving essential features, enabling efficient quantum or classical post-processing for tasks like reconstruction and classification. By leveraging the mathematical properties of orthogonal polynomials, the framework enhances circuit expressivity and stabilizes training compared to conventional hardware-efficient VQCs. Numerical experiments demonstrate PolyQROM's effectiveness in reconstructing flow fields with high fidelity and classifying flow patterns with accuracy surpassing classical methods and quantum benchmarks, all while reducing computational complexity and parameter counts. The work bridges quantum simulation outputs with practical fluid analysis, addressing the ``output problem'' through efficient reduced-order modeling tailored for quantum-encoded flow data, offering a scalable pathway to exploit quantum advantages in computational fluid dynamics.

Keywords

Cite

@article{arxiv.2504.21567,
  title  = {PolyQROM: Orthogonal-Polynomial-Based Quantum Reduced-Order Model for Flow Field Analysis},
  author = {Yu Fang and Cheng Xue and Tai-Ping Sun and Xiao-Fan Xu and Xi-Ning Zhuang and Yun-Jie Wang and Chuang-Chao Ye and Teng-Yang Ma and Jia-Xuan Zhang and Huan-Yu Liu and Yu-Chun Wu and Zhao-Yun Chen and Guo-Ping Guo},
  journal= {arXiv preprint arXiv:2504.21567},
  year   = {2025}
}

Comments

12 pages, 12 figures

R2 v1 2026-06-28T23:16:40.906Z