49 research outputs found
Exploring Randomly Wired Neural Networks for Climate Model Emulation
Exploring the climate impacts of various anthropogenic emissions scenarios is
key to making informed decisions for climate change mitigation and adaptation.
State-of-the-art Earth system models can provide detailed insight into these
impacts, but have a large associated computational cost on a per-scenario
basis. This large computational burden has driven recent interest in developing
cheap machine learning models for the task of climate model emulation. In this
manuscript, we explore the efficacy of randomly wired neural networks for this
task. We describe how they can be constructed and compare them to their
standard feedforward counterparts using the ClimateBench dataset. Specifically,
we replace the serially connected dense layers in multilayer perceptrons,
convolutional neural networks, and convolutional long short-term memory
networks with randomly wired dense layers and assess the impact on model
performance for models with 1 million and 10 million parameters. We find
average performance improvements of 4.2% across model complexities and
prediction tasks, with substantial performance improvements of up to 16.4% in
some cases. Furthermore, we find no significant difference in prediction speed
between networks with standard feedforward dense layers and those with randomly
wired layers. These findings indicate that randomly wired neural networks may
be suitable direct replacements for traditional dense layers in many standard
models
Detecting anthropogenic cloud perturbations with deep learning
One of the most pressing questions in climate science is that of the effect
of anthropogenic aerosol on the Earth's energy balance. Aerosols provide the
`seeds' on which cloud droplets form, and changes in the amount of aerosol
available to a cloud can change its brightness and other physical properties
such as optical thickness and spatial extent. Clouds play a critical role in
moderating global temperatures and small perturbations can lead to significant
amounts of cooling or warming. Uncertainty in this effect is so large it is not
currently known if it is negligible, or provides a large enough cooling to
largely negate present-day warming by CO2. This work uses deep convolutional
neural networks to look for two particular perturbations in clouds due to
anthropogenic aerosol and assess their properties and prevalence, providing
valuable insights into their climatic effects.Comment: Awarded Best Paper and Spotlight Oral at Climate Change: How Can AI
Help? (Workshop) at International Conference on Machine Learning (ICML), Long
Beach, California, 201
Cumulo: A Dataset for Learning Cloud Classes
One of the greatest sources of uncertainty in future climate projections
comes from limitations in modelling clouds and in understanding how different
cloud types interact with the climate system. A key first step in reducing this
uncertainty is to accurately classify cloud types at high spatial and temporal
resolution. In this paper, we introduce Cumulo, a benchmark dataset for
training and evaluating global cloud classification models. It consists of one
year of 1km resolution MODIS hyperspectral imagery merged with pixel-width
'tracks' of CloudSat cloud labels. Bringing these complementary datasets
together is a crucial first step, enabling the Machine-Learning community to
develop innovative new techniques which could greatly benefit the Climate
community. To showcase Cumulo, we provide baseline performance analysis using
an invertible flow generative model (IResNet), which further allows us to
discover new sub-classes for a given cloud class by exploring the latent space.
To compare methods, we introduce a set of evaluation criteria, to identify
models that are not only accurate, but also physically-realistic. CUMULO can be
download from
https://www.dropbox.com/sh/6gca7f0mb3b0ikz/AADq2lk4u7k961Qa31FwIDEpa?dl=0
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Community Intercomparison Suite (CIS) v1.4.0: a tool for intercomparing models and observations
The Community Intercomparison Suite (CIS) is an easy-to-use command-line tool which has been developed to allow the straightforward intercomparison of remote sensing, in situ and model data. While there are a number of tools available for working with climate model data, the large diversity of sources (and formats) of remote sensing and in situ measurements necessitated a novel software solution. Developed by a professional software company, CIS supports a large number of gridded and ungridded data sources "out-of-the-box", including climate model output in NetCDF or the UK Met Office pp file format, CloudSat, CALIOP (Cloud-Aerosol Lidar with Orthogonal Polarization), MODIS (MODerate resolution Imaging Spectroradiometer), Cloud and Aerosol CCI (Climate Change Initiative) level 2 satellite data and a number of in situ aircraft and ground station data sets. The open-source architecture also supports user-defined plugins to allow many other sources to be easily added. Many of the key operations required when comparing heterogenous data sets are provided by CIS, including subsetting, aggregating, collocating and plotting the data. Output data are written to CF-compliant NetCDF files to ensure interoperability with other tools and systems. The latest documentation, including a user manual and installation instructions, can be found on our website (http://cistools.net). Here, we describe the need which this tool fulfils, followed by descriptions of its main functionality (as at version 1.4.0) and plugin architecture which make it unique in the field
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Tobac 1.2: Towards a flexible framework for tracking and analysis of clouds in diverse datasets
We introduce tobac (Tracking and Object-Based Analysis of Clouds), a newly developed framework for tracking and analysing individual clouds in different types of datasets, such as cloud-resolving model simulations and geostationary satellite retrievals. The software has been designed to be used flexibly with any two-or three-dimensional timevarying input. The application of high-level data formats, such as Iris cubes or xarray arrays, for input and output allows for convenient use of metadata in the tracking analysis and visualisation. Comprehensive analysis routines are provided to derive properties like cloud lifetimes or statistics of cloud properties along with tools to visualise the results in a convenient way. The application of tobac is presented in two examples. We first track and analyse scattered deep convective cells based on maximum vertical velocity and the threedimensional condensate mixing ratio field in cloud-resolving model simulations. We also investigate the performance of the tracking algorithm for different choices of time resolution of the model output. In the second application, we show how the framework can be used to effectively combine information from two different types of datasets by simultaneously tracking convective clouds in model simulations and in geostationary satellite images based on outgoing longwave radiation. The tobac framework provides a flexible new way to include the evolution of the characteristics of individual clouds in a range of important analyses like model intercomparison studies or model assessment based on observational data. © 2019 Author(s)
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Increased water vapour lifetime due to global warming
Water vapour in the atmosphere is the source of a major climate feedback mechanism and potential increases in the availability of water vapour could have important consequences for mean and extreme precipitation. Future precipitation changes further depend on how the hydrological cycle responds to drivers of climate change, such as greenhouse gases and aerosols. Currently, neither the total anthropogenic influence on the hydrological cycle, nor those from individual drivers, are constrained sufficiently to make solid projections. We investigate how integrated water vapour (IWV) responds to different drivers of climate change. Results from 11 global climate models have been used, based on simulations where CO2, methane, solar irradiance, black carbon (BC), and sulphate have been perturbed separately. While the global-mean IWV is usually assumed to increase by ~7% per degree K surface temperature change, we find that the feedback response of IWV differs somewhat between drivers. Fast responses, which include the initial radiative effect and rapid adjustments to an external forcing, amplify these differences. The resulting net changes in IWV range from 6.4±0.9%/K for sulphate to 9.8±2%/K for BC. We further calculate the relationship between global changes in IWV and precipitation, which can be characterized by quantifying changes in atmospheric water vapour lifetime. Global climate models simulate a substantial increase in the lifetime, from 8.2±0.5 to 9.9±0.7 days between 1986-2005 and 2081-2100 under a high emission scenario, and we discuss to what extent the water vapour lifetime provides additional information compared to analysis of IWV and precipitation separately. We conclude that water vapour lifetime changes are an important indicator of changes in precipitation patterns and that BC is particularly efficient in prolonging the distance between evaporation and precipitation
ClimateBench v1.0: A benchmark for data-driven climate projections
Many different emission pathways exist that are compatible with the Paris climate agreement, and many more are possible that miss that target. While some of the most complex Earth System Models have simulated a small selection of Shared Socioeconomic Pathways, it is impractical to use these expensive models to fully explore the space of possibilities. Such explorations therefore mostly rely on one-dimensional impulse response models, or simple pattern scaling approaches to approximate the physical climate response to a given scenario. Here we present ClimateBench - a benchmarking framework based on a suite of CMIP, AerChemMIP and DAMIP simulations performed by a full complexity Earth System Model, and a set of baseline machine learning models that emulate its response to a variety of forcers. These emulators can predict annual mean global distributions of temperature, diurnal temperature range and precipitation (including extreme precipitation) given a wide range of emissions and concentrations of carbon dioxide, methane and aerosols, allowing them to efficiently probe previously unexplored scenarios. We discuss the accuracy and interpretability of these emulators and consider their robustness to physical constraints such as total energy conservation. Future opportunities incorporating such physical constraints directly in the machine learning models and using the emulators for detection and attribution studies are also discussed. This opens a wide range of opportunities to improve prediction, consistency and mathematical tractability. We hope that by laying out the principles of climate model emulation with clear examples and metrics we encourage others to tackle this important and demanding challenge
Opportunistic experiments to constrain aerosol effective radiative forcing
Aerosol–cloud interactions (ACIs) are considered to be the most uncertain driver of present-day radiative forcing due to human activities. The nonlinearity of cloud-state changes to aerosol perturbations make it challenging to attribute causality in observed relationships of aerosol radiative forcing. Using correlations to infer causality can be challenging when meteorological variability also drives both aerosol and cloud changes independently. Natural and anthropogenic aerosol perturbations from well-defined sources provide “opportunistic experiments” (also known as natural experiments) to investigate ACI in cases where causality may be more confidently inferred. These perturbations cover a wide range of locations and spatiotemporal scales, including point sources such as volcanic eruptions or industrial sources, plumes from biomass burning or forest fires, and tracks from individual ships or shipping corridors. We review the different experimental conditions and conduct a synthesis of the available satellite datasets and field campaigns to place these opportunistic experiments on a common footing, facilitating new insights and a clearer understanding of key uncertainties in aerosol radiative forcing. Cloud albedo perturbations are strongly sensitive to background meteorological conditions. Strong liquid water path increases due to aerosol perturbations are largely ruled out by averaging across experiments. Opportunistic experiments have significantly improved process-level understanding of ACI, but it remains unclear how reliably the relationships found can be scaled to the global level, thus demonstrating a need for deeper investigation in order to improve assessments of aerosol radiative forcing and climate change