HOPE: An Automatically Differentiable High-Order Non-Oscillatory Finite-Volume Shallow-Water Dynamic Core
ID:653 View Protection:ATTENDEE Updated Time:2025-04-01 16:59:30 Hits:580 Oral Presentation

Start Time:2025-04-18 15:10(Asia/Shanghai)

Duration:10min

Session:S1-1 专题1.1 模式数值算法研究 » S1-1专题1.1 模式数值算法研究

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Abstract
An automatically differentiable, high-order non-oscillatory finite volume shallow water dynamic core has been constructed on a cubed sphere grid. This dynamic core has four advantageous properties: high order accuracy, essential non-oscillation, mass conservation, and scalability. Besides, the code development is based on PyTorch, enabling the model to run seamlessly on both CPU and GPU, while naturally possessing the capability of automatic differentiation. We named the new dynamic core as High Order Prediction Environment (HOPE). The spatial reconstruction is based on the two-dimensional tensor product polynomial (TPP) and the genuine two-dimensional Weighted Essentially Non-Oscillatory scheme. A novel panel boundary approach ensures that the accuracy can reach arbitrary order. These algorithms have very high degree of compatibility with GPU architecture, allowing the computational overhead to be mitigated through the utilization of GPU. The Low Mach number Approximate Riemann Solver scheme is adopted as Riemann solvers to determine fluxes on the Gaussian points on edges. Flux across the interface between each cell edge is computed using Gaussian quadrature, and the tendencies of prognostic variables are obtained by integration all the source terms and the fluxes across the cell boundaries. This shallow water dynamic core exhibits outstanding performance in ideal shallow water test cases. In the steady-state geostrophic flow, the 11th order scheme reduces errors to nearly double precision round-off error even on coarse grids. Furthermore, HOPE maintains the Rossby-Haurwitz wave over 100 days without collapse. To test the non-oscillation property, we designed a cylinder dam break case, the WENO approach effectively suppresses non-physical oscillation, and the genuine two-dimensional reconstruction exhibits significantly better isotropy than the dimension-by-dimension scheme.
Keywords
自动微分,高精度,动力框架,有限体积法,浅水波方程,无振荡格式
Speaker
周立隆
高级工程师 中国气象局地球系统数值预报中心

Submission Author
周立隆 中国气象局地球系统数值预报中心
薛巍 清华大学
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Important Date
  • Conference Date

    Apr 17

    2025

    to

    Apr 21

    2025

  • Apr 10 2025

    Draft paper submission deadline

  • Apr 28 2025

    Registration deadline

Sponsored By
中国科学院大气物理研究所
Organized By
中国科学院大气物理研究所
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