Convolutional variational autoencoder for Northeast US coastal wind and flood hazard data augmentation

The coasts of the Northeastern United States experience wind and flood damage as a result of extratropical cyclones (such as Nor’easters). However, recorded data is limited for hazard analysis and resilience evaluation. This paper describes a method that can efficiently augment the time series of ex...

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Bibliographic Details
Published in:Neural computing & applications Vol. 37; no. 16; pp. 9537 - 9564
Main Authors: Jia, Yiming, Sasani, Mehrdad
Format: Journal Article
Language:English
Published: London Springer London 01.06.2025
Springer Nature B.V
Subjects:
Artificial Intelligence
Computational Biology/Bioinformatics
Computational Science and Engineering
Computer Science
Cyclones
Data augmentation
Data Mining and Knowledge Discovery
Flood damage
Generative adversarial networks
Goodness of fit
Hazard assessment
Image Processing and Computer Vision
Machine learning
Multivariate analysis
Normal distribution
Original Article
Probability and Statistics in Computer Science
Statistical analysis
Time measurement
Time series
Wind damage
Wind speed
United States > US
Data augmentation
Extratropical cyclone
Wind speed
Flood elevation
Convolutional variational autoencoder
Time series
ISSN:0941-0643, 1433-3058
Online Access:Get full text
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Summary:The coasts of the Northeastern United States experience wind and flood damage as a result of extratropical cyclones (such as Nor’easters). However, recorded data is limited for hazard analysis and resilience evaluation. This paper describes a method that can efficiently augment the time series of extratropical cyclone severity measures (wind speed and flood elevation) by leveraging convolutional variational autoencoders, a deep learning technique. As a generative model, the proposed convolutional variational autoencoder learns the probability distribution of latent features (here, low-dimensional underlying characteristics of the time series) as a multivariate normal distribution. The augmented severity measure time series are then obtained in two steps: (1) randomly sampling data from the learned multivariate normal distribution and (2) using the randomly sampled data as the input to the decoder of the trained convolutional variational autoencoder to generate severity measures. A case study is conducted to evaluate the quality of the augmented wind speed and flood elevation time series of the extratropical cyclones recorded in Boston Harbor (adjacent to the city of Boston, Massachusetts). This study also demonstrates that the proposed method outperforms other established time series data augmentation methods (i.e., Dynamic Time Warping and Conditional Generative Adversarial Network). An application for hazard frequency analysis—modeling the joint probability of wind speed and flood elevation using a Gumbel copula—is also presented. The results demonstrate that the augmented data can significantly reduce the uncertainty of the estimated copula parameter while obtaining a goodness-of-fit metric value (negative log-likelihood) similar to that of the original, non-augmented data. The proposed convolutional variational autoencoder can be used to augment any time series data. The user-friendly codes are published.
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ISSN:0941-0643
1433-3058
DOI:10.1007/s00521-025-11085-w