Pitfalls of Climate Network Construction: A Statistical Perspective
- URL: http://arxiv.org/abs/2211.02888v1
- Date: Sat, 5 Nov 2022 11:59:55 GMT
- Title: Pitfalls of Climate Network Construction: A Statistical Perspective
- Authors: Moritz Haas, Bedartha Goswami, Ulrike von Luxburg
- Abstract summary: We simulate time-dependent isotropic random fields on the sphere and apply common network construction techniques.
We find several ways in which the uncertainty stemming from the estimation procedure has major impact on network characteristics.
- Score: 13.623860700196625
- License: http://creativecommons.org/licenses/by-sa/4.0/
- Abstract: Network-based analyses of dynamical systems have become increasingly popular
in climate science. Here we address network construction from a statistical
perspective and highlight the often ignored fact that the calculated
correlation values are only empirical estimates. To measure spurious behaviour
as deviation from a ground truth network, we simulate time-dependent isotropic
random fields on the sphere and apply common network construction techniques.
We find several ways in which the uncertainty stemming from the estimation
procedure has major impact on network characteristics. When the data has
locally coherent correlation structure, spurious link bundle teleconnections
and spurious high-degree clusters have to be expected. Anisotropic estimation
variance can also induce severe biases into empirical networks. We validate our
findings with ERA5 reanalysis data. Moreover we explain why commonly applied
resampling procedures are inappropriate for significance evaluation and propose
a statistically more meaningful ensemble construction framework. By
communicating which difficulties arise in estimation from scarce data and by
presenting which design decisions increase robustness, we hope to contribute to
more reliable climate network construction in the future.
Related papers
- Network Causal Effect Estimation In Graphical Models Of Contagion And Latent Confounding [2.654975444537834]
Key question in many network studies is whether the observed correlations between units are primarily due to contagion or latent confounding.
We propose network causal effect estimation strategies that provide unbiased and consistent estimates.
We evaluate the effectiveness of our methods with synthetic data and the validity of our assumptions using real-world networks.
arXiv Detail & Related papers (2024-11-02T22:12:44Z) - Generating Fine-Grained Causality in Climate Time Series Data for Forecasting and Anomaly Detection [67.40407388422514]
We design a conceptual fine-grained causal model named TBN Granger Causality.
Second, we propose an end-to-end deep generative model called TacSas, which discovers TBN Granger Causality in a generative manner.
We test TacSas on climate benchmark ERA5 for climate forecasting and the extreme weather benchmark of NOAA for extreme weather alerts.
arXiv Detail & Related papers (2024-08-08T06:47:21Z) - On the Identification of Temporally Causal Representation with Instantaneous Dependence [50.14432597910128]
Temporally causal representation learning aims to identify the latent causal process from time series observations.
Most methods require the assumption that the latent causal processes do not have instantaneous relations.
We propose an textbfIDentification framework for instantanetextbfOus textbfLatent dynamics.
arXiv Detail & Related papers (2024-05-24T08:08:05Z) - Advancing Counterfactual Inference through Nonlinear Quantile Regression [77.28323341329461]
We propose a framework for efficient and effective counterfactual inference implemented with neural networks.
The proposed approach enhances the capacity to generalize estimated counterfactual outcomes to unseen data.
Empirical results conducted on multiple datasets offer compelling support for our theoretical assertions.
arXiv Detail & Related papers (2023-06-09T08:30:51Z) - Network Synthetic Interventions: A Causal Framework for Panel Data Under
Network Interference [23.718967111004964]
We consider the estimation of unit-specific potential outcomes from panel data in the presence of spillover across units and unobserved confounding.
Key to our approach is a novel latent factor model that takes into account network interference and generalizes the factor models typically used in panel data settings.
arXiv Detail & Related papers (2022-10-20T15:44:05Z) - Regression modelling of spatiotemporal extreme U.S. wildfires via
partially-interpretable neural networks [0.0]
We propose a new methodological framework for performing extreme quantile regression using artificial neutral networks.
We unify linear, and additive, regression methodology with deep learning to create partially-interpretable neural networks.
arXiv Detail & Related papers (2022-08-16T07:42:53Z) - A Bayesian Deep Learning Approach to Near-Term Climate Prediction [12.870804083819603]
We pursue a complementary machine-learning-based approach to climate prediction.
In particular, we find that a feedforward convolutional network with a Densenet architecture is able to outperform a convolutional LSTM in terms of predictive skill.
arXiv Detail & Related papers (2022-02-23T00:28:36Z) - Prequential MDL for Causal Structure Learning with Neural Networks [9.669269791955012]
We show that the prequential minimum description length principle can be used to derive a practical scoring function for Bayesian networks.
We obtain plausible and parsimonious graph structures without relying on sparsity inducing priors or other regularizers which must be tuned.
We discuss how the the prequential score relates to recent work that infers causal structure from the speed of adaptation when the observations come from a source undergoing distributional shift.
arXiv Detail & Related papers (2021-07-02T22:35:21Z) - Quantifying Uncertainty in Deep Spatiotemporal Forecasting [67.77102283276409]
We describe two types of forecasting problems: regular grid-based and graph-based.
We analyze UQ methods from both the Bayesian and the frequentist point view, casting in a unified framework via statistical decision theory.
Through extensive experiments on real-world road network traffic, epidemics, and air quality forecasting tasks, we reveal the statistical computational trade-offs for different UQ methods.
arXiv Detail & Related papers (2021-05-25T14:35:46Z) - Supporting Optimal Phase Space Reconstructions Using Neural Network
Architecture for Time Series Modeling [68.8204255655161]
We propose an artificial neural network with a mechanism to implicitly learn the phase spaces properties.
Our approach is either as competitive as or better than most state-of-the-art strategies.
arXiv Detail & Related papers (2020-06-19T21:04:47Z) - On Disentangled Representations Learned From Correlated Data [59.41587388303554]
We bridge the gap to real-world scenarios by analyzing the behavior of the most prominent disentanglement approaches on correlated data.
We show that systematically induced correlations in the dataset are being learned and reflected in the latent representations.
We also demonstrate how to resolve these latent correlations, either using weak supervision during training or by post-hoc correcting a pre-trained model with a small number of labels.
arXiv Detail & Related papers (2020-06-14T12:47:34Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.