Geoscientific Model Development (May 2024)

LB-SCAM: a learning-based method for efficient large-scale sensitivity analysis and tuning of the Single Column Atmosphere Model (SCAM)

  • J. Guo,
  • J. Guo,
  • J. Zheng,
  • Y. Xu,
  • H. Fu,
  • H. Fu,
  • H. Fu,
  • W. Xue,
  • W. Xue,
  • L. Wang,
  • L. Wang,
  • L. Gan,
  • L. Gan,
  • P. Gao,
  • P. Gao,
  • P. Gao,
  • W. Wan,
  • W. Wan,
  • X. Wu,
  • X. Wu,
  • Z. Zhang,
  • L. Hu,
  • G. Xu,
  • X. Che

DOI
https://doi.org/10.5194/gmd-17-3975-2024
Journal volume & issue
Vol. 17
pp. 3975 – 3992

Abstract

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The single-column model, with its advantages of low computational cost and fast execution speed, can assist users in gaining a more intuitive understanding of the impact of parameters on the simulated results of climate models. It plays a crucial role in the study of parameterization schemes, allowing for a more direct exploration of the influence of parameters on climate model simulations. In this paper, we employed various methods to conduct sensitivity analyses on the 11 parameters of the Single Column Atmospheric Model (SCAM). We explored their impact on output variables such as precipitation, temperature, humidity, and cloud cover, among others, across five test cases. To further expedite experimentation, we utilized machine learning methods to train surrogate models for the aforementioned cases. Additionally, three-parameter joint perturbation experiments were conducted based on these surrogate models to validate the combined parameter effects on the results. Subsequently, targeting the sensitive parameter combinations identified from the aforementioned experiments, we further conducted parameter tuning for the corresponding test cases to minimize the discrepancy between the results of SCAM and observational data. Our proposed method not only enhances model performance but also expedites parameter tuning speed, demonstrating good generality at the same time.