A Physics-Aware Neural Network Approach for Flow Data Reconstruction From Satellite Observations

Schweri, Luca; Foucher, Sebastien; Tang, Jingwei; Azevedo, Vinícius; Günther, Tobias; Solenthaler, Barbara

doi:10.3389/fclim.2021.656505

Cited by 7 publications

(3 citation statements)

References 33 publications

(47 reference statements)

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“…It may also be worthwhile to consider other atmospheric variables such as the convective available potential energy (CAPE) and deep-layer wind shear (DLS) due to their strong correlation with severe convective storm activity such as the occurrence of thunderstorms and supercells (see, for example, Rädler et al, 2015;Tsonevsky et al, 2018;Chavas and Dawson II, 2021). Another possible extension would be to implement categorical scores directly in the loss function (see, for example, Lagerquist and Ebert-Uphoff, 2022) or even combine the ConvLSTM with a socalled physics-aware loss function (see, for example, Schweri et al, 2021;Cuomo et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

Adapting a deep convolutional RNN model with imbalanced regression loss for improved spatio-temporal forecasting of extreme wind speed events in the short to medium range

Scheepens

Schicker

Hlaváčková‐Schindler³

et al. 2023

Geosci. Model Dev.

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Abstract. The number of wind farms and amount of wind power production in Europe, both on- and offshore, have increased rapidly in the past years. To ensure grid stability and on-time (re)scheduling of maintenance tasks and to mitigate fees in energy trading, accurate predictions of wind speed and wind power are needed. Particularly, accurate predictions of extreme wind speed events are of high importance to wind farm operators as timely knowledge of these can both prevent damages and offer economic preparedness. This work explores the possibility of adapting a deep convolutional recurrent neural network (RNN)-based regression model to the spatio-temporal prediction of extreme wind speed events in the short to medium range (12 h lead time in 1 h intervals) through the manipulation of the loss function. To this end, a multi-layered convolutional long short-term memory (ConvLSTM) network is adapted with a variety of imbalanced regression loss functions that have been proposed in the literature: inversely weighted, linearly weighted and squared error-relevance area (SERA) loss. Forecast performance is investigated for various intensity thresholds of extreme events, and a comparison is made with the commonly used mean squared error (MSE) and mean absolute error (MAE) loss. The results indicate the inverse weighting method to most effectively shift the forecast distribution towards the extreme tail, thereby increasing the number of forecasted events in the extreme ranges, considerably boosting the hit rate and reducing the root-mean-squared error (RMSE) in those ranges. The results also show, however, that such improvements are invariably accompanied by a pay-off in terms of increased overcasting and false alarm ratio, which increase both with lead time and intensity threshold. The inverse weighting method most effectively balances this trade-off, with the weighted MAE loss scoring slightly better than the weighted MSE loss. It is concluded that the inversely weighted loss provides an effective way to adapt deep learning to the task of imbalanced spatio-temporal regression and its application to the forecasting of extreme wind speed events in the short to medium range.

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Section: Discussionmentioning

confidence: 99%

Adapting a deep convolutional RNN model with imbalanced regression loss for improved spatio-temporal forecasting of extreme wind speed events in the short to medium range

Scheepens

Schicker

Hlaváčková‐Schindler³

et al. 2023

Geosci. Model Dev.

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“…Closely related to superresolution are works that aim to reconstruct the vector field from a sparse set of scattered data. Prior works [SFT∗22, EMY∗20, YWS∗21] achieve flow field reconstruction by directly optimizing for the velocity vectors. Han et al [HTZ∗19] and Gu et al [GHCW21] reconstruct vector fields from a set of representative streamlines.…”

Section: Related Workmentioning

confidence: 99%

Neural Flow Map Reconstruction

Sahoo

Berger

2022

Computer Graphics Forum

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In this paper we present a reconstruction technique for the reduction of unsteady flow data based on neural representations of time‐varying vector fields. Our approach is motivated by the large amount of data typically generated in numerical simulations, and in turn the types of data that domain scientists can generate in situ that are compact, yet useful, for post hoc analysis. One type of data commonly acquired during simulation are samples of the flow map, where a single sample is the result of integrating the underlying vector field for a specified time duration. In our work, we treat a collection of flow map samples for a single dataset as a meaningful, compact, and yet incomplete, representation of unsteady flow, and our central objective is to find a representation that enables us to best recover arbitrary flow map samples. To this end, we introduce a technique for learning implicit neural representations of time‐varying vector fields that are specifically optimized to reproduce flow map samples sparsely covering the spatiotemporal domain of the data. We show that, despite aggressive data reduction, our optimization problem — learning a function‐space neural network to reproduce flow map samples under a fixed integration scheme — leads to representations that demonstrate strong generalization, both in the field itself, and using the field to approximate the flow map. Through quantitative and qualitative analysis across different datasets we show that our approach is an improvement across a variety of data reduction methods, and across a variety of measures ranging from improved vector fields, flow maps, and features derived from the flow map.

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“…Various statistical tools have been developed for FR [1,2], however substantial strides were made recently with the application of deep learning (DL) to the field [3,4,5]. Applications outside typical wind tunnel-like scenarios, such as reconstruction of atmospheric flows based on satellite imagery [6], have also been developed.…”

Section: Introduction and Related Workmentioning

confidence: 99%

Unsteady 2D Flow Reconstruction around Arbitrary Shapes via Conformal Mapping aided Deep Neural Networks

Özbay

2022

Preprint

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In many practical fluid dynamics experiments, measuring variables such as velocity and pressure is possible only at a limited number of sensor locations, or for a few two-dimensional planes in the flow. However, knowledge of the full fields is necessary to understand the dynamics of many flows. Deep learning reconstruction of full flow fields from sparse measurements has recently garnered significant research interest, as a way of overcoming this limitation. This task is referred to as the flow reconstruction (FR) task. In the present study, we propose a convolutional autoencoder based neural network model, dubbed FR3D, which enables FR to be carried out for three-dimensional flows around extruded 3D objects with arbitrary cross-sections. An innovative mapping approach, whereby multiple fluid domains are mapped to an annulus, enables FR3D to generalize its performance to objects not encountered during training. We conclusively demonstrate this generalization capability using a dataset composed of 80 training and 20 testing geometries, all randomly generated. We show that the FR3D model reconstructs pressure and velocity components with a few percentage points of error. Additionally, using these predictions, we accurately estimate the Q-criterion fields as well lift and drag forces on the geometries.

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A Physics-Aware Neural Network Approach for Flow Data Reconstruction From Satellite Observations

Cited by 7 publications

References 33 publications

Adapting a deep convolutional RNN model with imbalanced regression loss for improved spatio-temporal forecasting of extreme wind speed events in the short to medium range

Adapting a deep convolutional RNN model with imbalanced regression loss for improved spatio-temporal forecasting of extreme wind speed events in the short to medium range

Neural Flow Map Reconstruction

Unsteady 2D Flow Reconstruction around Arbitrary Shapes via Conformal Mapping aided Deep Neural Networks

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