Exploring the Use of Machine Learning to Improve Vertical Profiles of Temperature and Moisture

Katherine Haynes, Jason Stock, Jack Dostalek, Charles Anderson, Imme Ebert-Uphoff
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Abstract

Abstract Vertical profiles of temperature and dewpoint are useful in predicting deep convection that leads to severe weather which threatens property and lives. Currently, forecasters rely on observations from radiosonde launches and numerical weather prediction (NWP) models. Radiosonde observations are, however, temporally and spatially sparse, and NWP models contain inherent errors that influence short-term predictions of high impact events. This work explores using machine learning (ML) to postprocess NWP model forecasts, combining them with satellite data to improve vertical profiles of temperature and dewpoint. We focus on different ML architectures, loss functions, and input features to optimize predictions. Because we are predicting vertical profiles at 256 levels in the atmosphere, this work provides a unique perspective at using ML for 1-D tasks. Compared to baseline profiles from the Rapid Refresh (RAP), ML predictions offer the largest improvement for dewpoint, particularly in the mid- and upper-atmosphere. Temperature improvements are modest, but CAPE values are improved by up to 40%. Feature importance analyses indicate that the ML models are primarily improving incoming RAP biases. While additional model and satellite data offer some improvement to the predictions, architecture choice is more important than feature selection in fine-tuning the results. Our proposed deep residual UNet performs the best by leveraging spatial context from the input RAP profiles; however, the results are remarkably robust across model architecture. Further, uncertainty estimates for every level are well-calibrated and can provide useful information to forecasters.
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探索使用机器学习来改善温度和湿度的垂直分布
温度和露点的垂直剖面图对于预测导致严重天气威胁财产和生命的深层对流是有用的。目前,预报员依靠无线电探空仪发射和数值天气预报(NWP)模式的观测结果。然而,探空观测在时间和空间上都是稀疏的,而且NWP模式包含影响高撞击事件短期预测的固有误差。这项工作探索了使用机器学习(ML)对NWP模型预测进行后处理,并将其与卫星数据相结合,以改善温度和露点的垂直剖面。我们专注于不同的机器学习架构、损失函数和输入特征来优化预测。由于我们正在预测大气中256层的垂直剖面,因此这项工作为使用ML进行一维任务提供了独特的视角。与快速刷新(RAP)的基线剖面相比,ML预测在露点方面提供了最大的改进,特别是在中高层大气中。温度的改善是适度的,但CAPE值提高了高达40%。特征重要性分析表明,机器学习模型主要是改善传入的RAP偏差。虽然额外的模型和卫星数据为预测提供了一些改进,但在微调结果时,架构选择比特征选择更重要。我们提出的深度残差UNet通过利用来自输入RAP剖面的空间背景而表现最佳;然而,结果在整个模型体系结构中是非常健壮的。此外,每个水平的不确定性估计都经过了很好的校准,可以为预报员提供有用的信息。
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