Benjamin A. Toms scite author profile

Neural networks have become increasingly prevalent within the geosciences, although a common limitation of their usage has been a lack of methods to interpret what the networks learn and how they make decisions. As such, neural networks have often been used within the geosciences to most accurately identify a desired output given a set of inputs, with the interpretation of what the network learns used as a secondary metric to ensure the network is making the right decision for the right reason. Neural network interpretation techniques have become more advanced in recent years, however, and we therefore propose that the ultimate objective of using a neural network can also be the interpretation of what the network has learned rather than the output itself. We show that the interpretation of neural networks can enable the discovery of scientifically meaningful connections within geoscientific data. In particular, we use two methods for neural network interpretation called backward optimization and layerwise relevance propagation, both of which project the decision pathways of a network back onto the original input dimensions. To the best of our knowledge, LRP has not yet been applied to geoscientific research, and we believe it has great potential in this area. We show how these interpretation techniques can be used to reliably infer scientifically meaningful information from neural networks by applying them to common climate patterns. These results suggest that combining interpretable neural networks with novel scientific hypotheses will open the door to many new avenues in neural network‐related geoscience research.

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Indicator Patterns of Forced Change Learned by an Artificial Neural Network

Barnes

Toms

Hurrell

et al. 2020

J Adv Model Earth Syst

120

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Many problems in climate science require the identification of signals obscured by both the “noise” of internal climate variability and differences across models. Following previous work, we train an artificial neural network (ANN) to predict the year of a given map of annual‐mean temperature (or precipitation) from forced climate model simulations. This prediction task requires the ANN to learn forced patterns of change amidst a background of climate noise and model differences. We then apply a neural network visualization technique (layerwise relevance propagation) to visualize the spatial patterns that lead the ANN to successfully predict the year. These spatial patterns thus serve as “reliable indicators” of the forced change. The architecture of the ANN is chosen such that these indicators vary in time, thus capturing the evolving nature of regional signals of change. Results are compared to those of more standard approaches like signal‐to‐noise ratios and multilinear regression in order to gain intuition about the reliable indicators identified by the ANN. We then apply an additional visualization tool (backward optimization) to highlight where disagreements in simulated and observed patterns of change are most important for the prediction of the year. This work demonstrates that ANNs and their visualization tools make a powerful pair for extracting climate patterns of forced change.

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ClimateNet: an expert-labeled open dataset and deep learning architecture for enabling high-precision analyses of extreme weather

Prabhat¹,

Kashinath

Mudigonda

et al. 2021

Geosci. Model Dev.

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Abstract. Identifying, detecting, and localizing extreme weather events is a crucial first step in understanding how they may vary under different climate change scenarios. Pattern recognition tasks such as classification, object detection, and segmentation (i.e., pixel-level classification) have remained challenging problems in the weather and climate sciences. While there exist many empirical heuristics for detecting extreme events, the disparities between the output of these different methods even for a single event are large and often difficult to reconcile. Given the success of deep learning (DL) in tackling similar problems in computer vision, we advocate a DL-based approach. DL, however, works best in the context of supervised learning – when labeled datasets are readily available. Reliable labeled training data for extreme weather and climate events is scarce. We create “ClimateNet” – an open, community-sourced human-expert-labeled curated dataset that captures tropical cyclones (TCs) and atmospheric rivers (ARs) in high-resolution climate model output from a simulation of a recent historical period. We use the curated ClimateNet dataset to train a state-of-the-art DL model for pixel-level identification – i.e., segmentation – of TCs and ARs. We then apply the trained DL model to historical and climate change scenarios simulated by the Community Atmospheric Model (CAM5.1) and show that the DL model accurately segments the data into TCs, ARs, or “the background” at a pixel level. Further, we show how the segmentation results can be used to conduct spatially and temporally precise analytics by quantifying distributions of extreme precipitation conditioned on event types (TC or AR) at regional scales. The key contribution of this work is that it paves the way for DL-based automated, high-fidelity, and highly precise analytics of climate data using a curated expert-labeled dataset – ClimateNet. ClimateNet and the DL-based segmentation method provide several unique capabilities: (i) they can be used to calculate a variety of TC and AR statistics at a fine-grained level; (ii) they can be applied to different climate scenarios and different datasets without tuning as they do not rely on threshold conditions; and (iii) the proposed DL method is suitable for rapidly analyzing large amounts of climate model output. While our study has been conducted for two important extreme weather patterns (TCs and ARs) in simulation datasets, we believe that this methodology can be applied to a much broader class of patterns and applied to observational and reanalysis data products via transfer learning.

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Elastic and viscous properties of dilute solutions of polymethyl methacrylate in organic liquids

Toms¹,

Strawbridge²

1953

Trans. Faraday Soc.

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An investigation has been made into the variability and interconnections of three constants-a viscosity coefficient 70, a stress relaxation time A1 and a rate of strain relaxation time A2-which serve to characterize the behaviour of a dilute solution of highly polymerized methyl methacrylate in a simple shearing motion at small rates of strain. The principal experimental results, which refer to solutions containing between 1 and 10 % of polymer in toluene, pyridine, cyclohexanone and n-butyl acetate, were derived from observations with a coaxial-cylinder elastoviscometer at temperatures in the range 15" to 45" C . No large deviations of A2 from the value 0.015 sec were observed, but both 90 and A1 varied with polymer concentration, the nature of the solvent, and temperature ; values of A1 between 0.02 and 0.2 sec were found, and these corresponded with values of 70 between 1 and 20 poises. It is deduced that, under the experimental conditions, relaxation of shear stress and of rate of strain were effected by different processes, and this conclusion is thought to be consistent with current " molecular " theories of rubber-like elasticity and of the constitution, and viscous flow, of solutions of linear polymers.

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A Coaxial-Cylinder Elastoviscometer

1951

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Benjamin A. Toms

Physically Interpretable Neural Networks for the Geosciences: Applications to Earth System Variability

Indicator Patterns of Forced Change Learned by an Artificial Neural Network

ClimateNet: an expert-labeled open dataset and deep learning architecture for enabling high-precision analyses of extreme weather

Elastic and viscous properties of dilute solutions of polymethyl methacrylate in organic liquids

A Coaxial-Cylinder Elastoviscometer

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