Correction of approximation errors with Random Forests applied to modelling of cloud droplet formation

Lipponen, Antti; Kolehmainen, Ville; Romakkaniemi, Sami; Kokkola, Harri

doi:10.5194/gmd-6-2087-2013

Cited by 18 publications

(20 citation statements)

References 31 publications

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“…The probable reason why the LFRF method performs so well, outperforming even GPE, is that it is supported with an embedded dependency, the linear model LF. This is in line with Lipponen et al (2013Lipponen et al ( , 2018 where they showed that including a dependency (= correcting a rough empirical model with random forest) improved results compared to a pure random forest learning method. LF is the least accurate method in all simulation sets, except in SALSA day where it outperforms the GPE only slightly.…”

Section: Parameterisation Intercomparisonsupporting

confidence: 85%

“…The approach used in this study is similar to the approximation error correction method introduced in Lipponen et al (2013) and Lipponen et al (2018). In Lipponen et al (2018), it was shown that predicting and correcting the approximation error of the output of an approximative model often leads to more accurate results than directly predicting the model output.…”

Section: Linear Fit Improved With Random Forest (Lfrf)mentioning

confidence: 99%

“…The parameterisations are based on detailed LES runs. The three methods are based on 1) a Gaussian process emulator, 2) a linear parameterisation based on cloud radiative cooling (Zheng et al, 2016), and 3) machine learning to correct the approximation error of the linear fit obtained with method 2 (Lipponen et al, 2013(Lipponen et al, , 2018. We also examine which parameters are most important for predicting updraft velocities.…”

Section: Introductionmentioning

confidence: 99%

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Parameterising cloud base updraft velocity of marine stratocumuli

Ahola

Raatikainen

Alper

et al. 2021

Preprint

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Abstract. The number of cloud droplets formed at the cloud base depends both on the properties of aerosol particles and the updraft velocity of an air parcel at the cloud base. As the spatial scale of updrafts is too small to be resolved in global atmospheric models, the updraft velocity is commonly parameterised based on the available turbulent kinetic energy. Here we present alternative methods through parameterising updraft velocity based on high-resolution large eddy simulation (LES) runs in the case of marine stratocumulus clouds. First we use our simulations to assess the accuracy of a simple linear parametrisation where the updraft velocity depends only on cloud top radiative cooling. In addition, we present two different machine learning methods (Gaussian process emulation and random forest) that account for different boundary layer conditions and cloud properties. We conclude that both machine learning parameterisations reproduce the LES-based updraft velocities at about the same accuracy, while the simple approach employing radiative cooling only produce on average lower coefficient of determination and higher root mean square error values. Finally, we apply these machine learning methods to find the key parameters affecting cloud base updraft velocities.

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Section: Parameterisation Intercomparisonsupporting

confidence: 85%

Section: Linear Fit Improved With Random Forest (Lfrf)mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Parameterising cloud base updraft velocity of marine stratocumuli

Ahola

Raatikainen

Alper

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…More specifically, we train the machine learning model for post-process correction of the approximation error in the result of the conventional retrieval algorithm. While the postprocess correction approach is new to satellite retrievals, it has been found to perform better and produce more stable and accurate results than a fully learned approach in generation of surrogate simulation models (Lipponen et al, 2013(Lipponen et al, , 2018 and in medical imaging, where many of the inverse imaging problems are mathematically highly similar to the satellite retrieval problems; see for example Hamilton et al (2019). The key advantages of the new modelenforced post-process correction approach are (1) the improved accuracy over the existing data products and existing fully learned satellite data approaches and (2) the possibility to post-process-correct existing (past) satellite data products with no need for full re-processing of the enormous satellite datasets.…”

Section: Introductionmentioning

confidence: 99%

Model-enforced post-process correction of satellite aerosol retrievals

et al. 2021

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Abstract. Satellite-based aerosol retrievals provide a timely view of atmospheric aerosol properties, having a crucial role in the subsequent estimation of air quality indicators, atmospherically corrected satellite data products, and climate applications. However, current aerosol data products based on satellite data often have relatively large biases compared to accurate ground-based measurements and distinct uncertainty levels associated with them. These biases and uncertainties are often caused by oversimplified assumptions and approximations used in the retrieval algorithms due to unknown surface reflectance or fixed aerosol models. Moreover, the retrieval algorithms do not usually take advantage of all the possible observational data collected by the satellite instruments and may, for example, leave some spectral bands unused. The improvement and the re-processing of the past and current operational satellite data retrieval algorithms would become tedious and computationally expensive. To overcome this burden, we have developed a model-enforced post-process correction approach to correct the existing operational satellite aerosol data products. Our approach combines the existing satellite aerosol retrievals and a post-processing step carried out with a machine-learning-based correction model for the approximation error in the retrieval. The developed approach allows for the utilization of auxiliary data sources, such as meteorological information, or additional observations such as spectral bands unused by the original retrieval algorithm. The post-process correction model can learn to correct for the biases and uncertainties in the original retrieval algorithms. As the correction is carried out as a post-processing step, it allows for computationally efficient re-processing of existing satellite aerosol datasets without fully re-processing the much larger original radiance data. We demonstrate with over-land aerosol optical depth (AOD) and Ångström exponent (AE) data from the Moderate Imaging Spectroradiometer (MODIS) of the Aqua satellite that our approach can significantly improve the accuracy of the satellite aerosol data products and reduce the associated uncertainties. For instance, in our evaluation, the number of AOD samples within the MODIS Dark Target expected error envelope increased from 63 % to 85 % when the post-process correction was applied. In addition to method description and accuracy results, we also give recommendations for validating machine-learning-based satellite data products.

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“…More specifically, we train the machine learning model for post-process correction of the approximation error in the result of the conventional retrieval algorithm. While the post-process correction approach is new to satellite retrievals, it has been found to perform better and produce more stable and accurate results than a fully learned approach in generation of surrogate simulation models (Lipponen et al, 2013(Lipponen et al, , 2018 and in medical imaging, where many of the inverse imaging problems are mathematically highly similar to the satellite retrieval problems, see for example Hamilton et al (2019). The key advantages of the new model enforced post-process correction approach are 1) the improved accuracy over the existing data products and existing fully learned satellite data approaches, and 2) the possibility to post-process correct existing (past) satellite data products with no need for full re-processing of the enormous satellite datasets.…”

mentioning

confidence: 99%

Model Enforced Post-Process Correction of Satellite Aerosol Retrievals

Lipponen¹,

Kolehmainen²,

Kolmonen³

et al. 2020

Preprint

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Abstract. Satellite-based aerosol retrievals provide a timely global view of atmospheric aerosol properties for air quality, atmospheric characterization, and correction of satellite data products and climate applications. Current aerosol data products based on satellite data, however, often have relatively large biases relative to accurate ground-based measurements and distinct levels of uncertainty associated with them. These biases and uncertainties are often caused by oversimplified assumptions and approximations used in the retrieval algorithms due to unknown surface reflectance or fixed aerosol models. Moreover, the retrieval algorithms do not usually take advantage of all the possible observational data collected by the satellite instruments and may, for example, leave some spectral bands unused. The improvement and the re-processing of the past and current operational satellite data retrieval algorithms would become a tedious and computationally expensive task. To overcome this burden, we have developed a model enforced post-process correction approach that can be used to correct the existing and operational satellite aerosol data products. Our approach combines the existing satellite aerosol retrievals and a post-processing step carried out with a machine learning based correction model for the approximation error in the retrieval. The developed approach allows for the utilization of auxiliary data sources, such as meteorological information, or additional observations such as spectral bands unused by the original retrieval algorithm. The post-process correction model can learn to correct for the biases and uncertainties in the original retrieval algorithms. As the correction is carried out as a post-processing step, it allows for computationally efficient re-processing of existing satellite aerosol datasets with no need to fully reprocess the much larger original radiance data. We demonstrate with over land aerosol optical depth (AOD) and Angstrom exponent (AE) data from the Moderate Imaging Spectroradiometer (MODIS) of Aqua satellite that our approach can significantly improve the accuracy of the satellite aerosol data products and reduce the associated uncertainties. We also give recommendations for the validation of satellite data products that are constructed using machine learning based models.

show abstract

Correction of approximation errors with Random Forests applied to modelling of cloud droplet formation

Cited by 18 publications

References 31 publications

Parameterising cloud base updraft velocity of marine stratocumuli

Parameterising cloud base updraft velocity of marine stratocumuli

Model-enforced post-process correction of satellite aerosol retrievals

Model Enforced Post-Process Correction of Satellite Aerosol Retrievals

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