Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases

Aikaterini P. Kyprioti; Alexandros A. Taflanidis; Matthew Plumlee; Taylor G. Asher; Elaine Spiller; Richard A. Luettich; Brian Blanton; Tracy L. Kijewski-Correa; Andrew Kennedy; Lauren Schmied

doi:10.1007/s11069-021-04881-9

Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases

Aikaterini P. Kyprioti, Alexandros A. Taflanidis^*, Matthew Plumlee, Taylor G. Asher, Elaine Spiller, Richard A. Luettich, Brian Blanton, Tracy L. Kijewski-Correa, Andrew Kennedy, Lauren Schmied

^*Corresponding author for this work

Industrial Engineering and Management Sciences

Research output: Contribution to journal › Article › peer-review

13 Scopus citations

Abstract

Surrogate models are becoming increasingly popular for storm surge predictions. Using existing databases of storm simulations, developed typically during regional flood studies, these models provide fast-to-compute, data-driven approximations quantifying the expected storm surge for any new storm (not included in the training database). This paper considers the development of such a surrogate model for Delaware Bay, using a database of 156 simulations driven by synthetic tropical cyclones and offering predictions for a grid that includes close to 300,000 computational nodes within the geographical domain of interest. Kriging (Gaussian Process regression) is adopted as the surrogate modeling technique, and various relevant advancements are established. The appropriate parameterization of the synthetic storm database is examined. For this, instead of the storm features at landfall, the features when the storm is at closest distance to some representative point of the domain of interest are investigated as an alternative parametrization, and are found to produce a better surrogate. For nodes that remained dry for some of the database storms, imputation of the surge using a weighted k nearest neighbor (kNN) interpolation is considered to fill in the missing data. The use of a secondary, classification surrogate model, combining logistic principal component analysis and Kriging, is examined to address instances for which the imputed surge leads to misclassification of the node condition. Finally, concerns related to overfitting for the surrogate model are discussed, stemming from the small size of the available database. These concerns extend to both the calibration of the surrogate model hyper-parameters, as well as to the validation approaches adopted. During this process, the benefits from the use of principal component analysis as a dimensionality reduction technique, and the appropriate transformation and scaling of the surge output are examined in detail.

Original language	English (US)
Pages (from-to)	1349-1386
Number of pages	38
Journal	Natural Hazards
Volume	109
Issue number	2
DOIs	https://doi.org/10.1007/s11069-021-04881-9
State	Published - Nov 2021

Funding

This work was supported by the U.S. Department of Homeland Security Coastal Resilience Center (CRC) under Grant Award Number 2015-ST-061-ND0001-01. Specific funding was provided to the Coastal Resilience Center by the Federal Emergency Management Agency via the DHS Basic Ordering Agreement HSHQDC-16-A-B0011. The views and conclusions contained herein are those of the authors and should not be interpreted as representing the official policies, either expressed or implied, of the U.S Department of Homeland Security or the Federal Emergency Management Agency. This work was supported by the U.S. Department of Homeland Security Coastal Resilience Center (CRC) under Grant Award Number 2015-ST-061-ND0001-01. Specific funding was provided to the Coastal Resilience Center by the Federal Emergency Management Agency via the DHS Basic Ordering Agreement HSHQDC-16-A-B0011. This work was supported by the U.S. Department of Homeland Security Coastal Resilience Center (CRC) under Grant Award Number 2015-ST-061-ND0001-01. Specific funding was provided to the Coastal Resilience Center by the Federal Emergency Management Agency via the DHS Basic Ordering Agreement HSHQDC-16-A-B0011. The views and conclusions contained herein are those of the authors and should not be interpreted as representing the official policies, either expressed or implied, of the U.S Department of Homeland Security or the Federal Emergency Management Agency. Plan is to make the database of synthetic storms used in this study available through the National Science Foundation (NSF) NHERI (Natural Hazards Engineering Research Infrastructure) Computational Modeling and Simulation Center (SimCenter) https://simcenter.designsafe-ci.org/ . Discussions and data transfer are currently ongoing.

Keywords

Binary classification
Dry node imputation
Gaussian process
Kriging
Overfitting
Storm parameterization
Storm surge surrogate model

ASJC Scopus subject areas

Water Science and Technology
Atmospheric Science
Earth and Planetary Sciences (miscellaneous)

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Cite this

Kyprioti, A. P., Taflanidis, A. A., Plumlee, M., Asher, T. G., Spiller, E., Luettich, R. A., Blanton, B., Kijewski-Correa, T. L., Kennedy, A., & Schmied, L. (2021). Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases. Natural Hazards, 109(2), 1349-1386. https://doi.org/10.1007/s11069-021-04881-9

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title = "Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases",

abstract = "Surrogate models are becoming increasingly popular for storm surge predictions. Using existing databases of storm simulations, developed typically during regional flood studies, these models provide fast-to-compute, data-driven approximations quantifying the expected storm surge for any new storm (not included in the training database). This paper considers the development of such a surrogate model for Delaware Bay, using a database of 156 simulations driven by synthetic tropical cyclones and offering predictions for a grid that includes close to 300,000 computational nodes within the geographical domain of interest. Kriging (Gaussian Process regression) is adopted as the surrogate modeling technique, and various relevant advancements are established. The appropriate parameterization of the synthetic storm database is examined. For this, instead of the storm features at landfall, the features when the storm is at closest distance to some representative point of the domain of interest are investigated as an alternative parametrization, and are found to produce a better surrogate. For nodes that remained dry for some of the database storms, imputation of the surge using a weighted k nearest neighbor (kNN) interpolation is considered to fill in the missing data. The use of a secondary, classification surrogate model, combining logistic principal component analysis and Kriging, is examined to address instances for which the imputed surge leads to misclassification of the node condition. Finally, concerns related to overfitting for the surrogate model are discussed, stemming from the small size of the available database. These concerns extend to both the calibration of the surrogate model hyper-parameters, as well as to the validation approaches adopted. During this process, the benefits from the use of principal component analysis as a dimensionality reduction technique, and the appropriate transformation and scaling of the surge output are examined in detail.",

keywords = "Binary classification, Dry node imputation, Gaussian process, Kriging, Overfitting, Storm parameterization, Storm surge surrogate model",

author = "Kyprioti, {Aikaterini P.} and Taflanidis, {Alexandros A.} and Matthew Plumlee and Asher, {Taylor G.} and Elaine Spiller and Luettich, {Richard A.} and Brian Blanton and Kijewski-Correa, {Tracy L.} and Andrew Kennedy and Lauren Schmied",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Nature B.V.",

year = "2021",

month = nov,

doi = "10.1007/s11069-021-04881-9",

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Kyprioti, AP, Taflanidis, AA, Plumlee, M, Asher, TG, Spiller, E, Luettich, RA, Blanton, B, Kijewski-Correa, TL, Kennedy, A & Schmied, L 2021, 'Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases', Natural Hazards, vol. 109, no. 2, pp. 1349-1386. https://doi.org/10.1007/s11069-021-04881-9

TY - JOUR

T1 - Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases

AU - Kyprioti, Aikaterini P.

AU - Taflanidis, Alexandros A.

AU - Plumlee, Matthew

AU - Asher, Taylor G.

AU - Spiller, Elaine

AU - Luettich, Richard A.

AU - Blanton, Brian

AU - Kijewski-Correa, Tracy L.

AU - Kennedy, Andrew

AU - Schmied, Lauren

PY - 2021/11

Y1 - 2021/11

N2 - Surrogate models are becoming increasingly popular for storm surge predictions. Using existing databases of storm simulations, developed typically during regional flood studies, these models provide fast-to-compute, data-driven approximations quantifying the expected storm surge for any new storm (not included in the training database). This paper considers the development of such a surrogate model for Delaware Bay, using a database of 156 simulations driven by synthetic tropical cyclones and offering predictions for a grid that includes close to 300,000 computational nodes within the geographical domain of interest. Kriging (Gaussian Process regression) is adopted as the surrogate modeling technique, and various relevant advancements are established. The appropriate parameterization of the synthetic storm database is examined. For this, instead of the storm features at landfall, the features when the storm is at closest distance to some representative point of the domain of interest are investigated as an alternative parametrization, and are found to produce a better surrogate. For nodes that remained dry for some of the database storms, imputation of the surge using a weighted k nearest neighbor (kNN) interpolation is considered to fill in the missing data. The use of a secondary, classification surrogate model, combining logistic principal component analysis and Kriging, is examined to address instances for which the imputed surge leads to misclassification of the node condition. Finally, concerns related to overfitting for the surrogate model are discussed, stemming from the small size of the available database. These concerns extend to both the calibration of the surrogate model hyper-parameters, as well as to the validation approaches adopted. During this process, the benefits from the use of principal component analysis as a dimensionality reduction technique, and the appropriate transformation and scaling of the surge output are examined in detail.

AB - Surrogate models are becoming increasingly popular for storm surge predictions. Using existing databases of storm simulations, developed typically during regional flood studies, these models provide fast-to-compute, data-driven approximations quantifying the expected storm surge for any new storm (not included in the training database). This paper considers the development of such a surrogate model for Delaware Bay, using a database of 156 simulations driven by synthetic tropical cyclones and offering predictions for a grid that includes close to 300,000 computational nodes within the geographical domain of interest. Kriging (Gaussian Process regression) is adopted as the surrogate modeling technique, and various relevant advancements are established. The appropriate parameterization of the synthetic storm database is examined. For this, instead of the storm features at landfall, the features when the storm is at closest distance to some representative point of the domain of interest are investigated as an alternative parametrization, and are found to produce a better surrogate. For nodes that remained dry for some of the database storms, imputation of the surge using a weighted k nearest neighbor (kNN) interpolation is considered to fill in the missing data. The use of a secondary, classification surrogate model, combining logistic principal component analysis and Kriging, is examined to address instances for which the imputed surge leads to misclassification of the node condition. Finally, concerns related to overfitting for the surrogate model are discussed, stemming from the small size of the available database. These concerns extend to both the calibration of the surrogate model hyper-parameters, as well as to the validation approaches adopted. During this process, the benefits from the use of principal component analysis as a dimensionality reduction technique, and the appropriate transformation and scaling of the surge output are examined in detail.

KW - Binary classification

KW - Dry node imputation

KW - Gaussian process

KW - Kriging

KW - Overfitting

KW - Storm parameterization

KW - Storm surge surrogate model

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Improvements in storm surge surrogate modeling for synthetic storm parameterization, node condition classification and implementation to small size databases

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