An efficient artificial intelligence model for prediction of tropical storm surge

Research output: Contribution to journalArticlepeer-review

Standard Standard

An efficient artificial intelligence model for prediction of tropical storm surge. / Hashemi, M. Reza ; Spaulding, Malcolm L.; Shaw, Alex et al.
In: Natural Hazards, Vol. 82, 05.2016, p. 471-491.

Research output: Contribution to journalArticlepeer-review

HarvardHarvard

Hashemi, MR, Spaulding, ML, Shaw, A, Farhadi, H & Lewis, M 2016, 'An efficient artificial intelligence model for prediction of tropical storm surge', Natural Hazards, vol. 82, pp. 471-491. https://doi.org/10.1007/s11069-016-2193-4

APA

Hashemi, M. R., Spaulding, M. L., Shaw, A., Farhadi, H., & Lewis, M. (2016). An efficient artificial intelligence model for prediction of tropical storm surge. Natural Hazards, 82, 471-491. https://doi.org/10.1007/s11069-016-2193-4

CBE

MLA

VancouverVancouver

Hashemi MR, Spaulding ML, Shaw A, Farhadi H, Lewis M. An efficient artificial intelligence model for prediction of tropical storm surge. Natural Hazards. 2016 May;82:471-491. Epub 2016 Feb 9. doi: 10.1007/s11069-016-2193-4

Author

Hashemi, M. Reza ; Spaulding, Malcolm L. ; Shaw, Alex et al. / An efficient artificial intelligence model for prediction of tropical storm surge. In: Natural Hazards. 2016 ; Vol. 82. pp. 471-491.

RIS

TY - JOUR

T1 - An efficient artificial intelligence model for prediction of tropical storm surge

AU - Hashemi, M. Reza

AU - Spaulding, Malcolm L.

AU - Shaw, Alex

AU - Farhadi, Hamed

AU - Lewis, Matthew

N1 - This work was undertaken with funding support from a Rhode Island Community Development Block Grant (4712) from the US Department of Housing and Urban Development and the state of Rhode Island Division of Planning Office of Housing and Community Development. Matt Lewis is funded by the Welsh Government Ser Cymru QUOTIENT project.

PY - 2016/5

Y1 - 2016/5

N2 - Process-based models have been widely used for storm surge predictions, but their high computational demand is a major drawback in some applications such as rapid forecasting. Few efforts have been made to employ previous databases of synthetic/real storms and provide more efficient surge predictions (e.g. using storm similarity of an individual storm to those in the database). Here, we develop an alternative efficient and robust artificial intelligent model, which predicts the peak storm surge using the tropical storm parameters: central pressure, radius to maximum winds, forward velocity, and storm track. The US Army Corp of Engineers, North Atlantic Comprehensive Coastal Study, has recently performed numerical simulations of 1050 synthetic tropical storms, which statistically represent tropical storms, using a coupled high resolution wave–surge modeling system for the east coast of the US, from Cape Hatteras to the Canadian border. This study has provided an unprecedented dataset which can be used to train artificial intelligence models for surge prediction in those areas. While numerical simulation of a storm surge at this scale and resolution (over 6 million elements scaling from 20 m to more than 100 km) is extremely expensive, the artificial intelligence takes the advantage of the previous simulations, and effectively learns the relationship between storm parameters representing storm forcing and surge. The artificial neural network method which was used for this study, was shown to outperform support vector machine for extreme storms. ANN model, which is based on a neurobiological analogy, can be conveniently developed, retrained by new data, and is nonparametric. The AI model, which was developed for Rhode Island, was validated using a set of randomly selected synthetic storms as well as real tropical storms in this region. The model performance was found satisfactory with root-mean-square error of <35 cm for observed and synthetic storms. It was also shown that it is not possible to develop a reliable artificial intelligence model for this region using a limited number of data (e.g. 200 storms), which is usually available in historical records.

AB - Process-based models have been widely used for storm surge predictions, but their high computational demand is a major drawback in some applications such as rapid forecasting. Few efforts have been made to employ previous databases of synthetic/real storms and provide more efficient surge predictions (e.g. using storm similarity of an individual storm to those in the database). Here, we develop an alternative efficient and robust artificial intelligent model, which predicts the peak storm surge using the tropical storm parameters: central pressure, radius to maximum winds, forward velocity, and storm track. The US Army Corp of Engineers, North Atlantic Comprehensive Coastal Study, has recently performed numerical simulations of 1050 synthetic tropical storms, which statistically represent tropical storms, using a coupled high resolution wave–surge modeling system for the east coast of the US, from Cape Hatteras to the Canadian border. This study has provided an unprecedented dataset which can be used to train artificial intelligence models for surge prediction in those areas. While numerical simulation of a storm surge at this scale and resolution (over 6 million elements scaling from 20 m to more than 100 km) is extremely expensive, the artificial intelligence takes the advantage of the previous simulations, and effectively learns the relationship between storm parameters representing storm forcing and surge. The artificial neural network method which was used for this study, was shown to outperform support vector machine for extreme storms. ANN model, which is based on a neurobiological analogy, can be conveniently developed, retrained by new data, and is nonparametric. The AI model, which was developed for Rhode Island, was validated using a set of randomly selected synthetic storms as well as real tropical storms in this region. The model performance was found satisfactory with root-mean-square error of <35 cm for observed and synthetic storms. It was also shown that it is not possible to develop a reliable artificial intelligence model for this region using a limited number of data (e.g. 200 storms), which is usually available in historical records.

U2 - 10.1007/s11069-016-2193-4

DO - 10.1007/s11069-016-2193-4

M3 - Article

VL - 82

SP - 471

EP - 491

JO - Natural Hazards

JF - Natural Hazards

SN - 0921-030X

ER -