Developing tsunami fragility curves based on the satellite remote sensing and the numerical modeling of the 2004 Indian Ocean tsunami in Thailand

Suppasri, Anawat; Koshimura, Shunichi; Imamura, Fumihiko

doi:10.5194/nhess-11-173-2011

Cited by 147 publications

(90 citation statements)

References 6 publications

(13 reference statements)

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“…This issue is addressed in some studies by re-grouping buildings into bins with approximately equal number of buildings, resulting in some bins corresponding to a rather wide range of intensity measure levels. For instance, Suppasri et al (2011) formed even bins of 50 buildings (Phuket) and 100 buildings (Phang Nga); Suppasri et al (2012) formed bins of 15 buildings in the study areas of Sendai and Ishinomaki. However, this re-grouping can affect the shape of the fragility curve especially at the tails.…”

Section: Introductionmentioning

confidence: 99%

Empirical fragility assessment of buildings affected by the 2011 Great East Japan tsunami using improved statistical models

et al. 2014

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Tsunamis are destructive natural phenomena which cause extensive damage to the built environment, affecting the livelihoods and economy of the impacted nations. This has been demonstrated by the tragic events of the Indian Ocean tsunami in 2004, or the Great East Japan tsunami in 2011. Following such events, a few studies have attempted to assess the fragility of the existing building inventory by constructing empirical stochastic functions, which relate the damage to a measure of tsunami intensity. However, these studies typically fit a linear statistical model to the available damage data, which are aggregated in bins of similar levels of tsunami intensity. This procedure, however, cannot deal well with aggregated data, low and high damage probabilities, nor does it result in the most realistic representation of the tsunami-induced damage. Deviating from this trend, the present study adopts the more realistic generalised linear models which address the aforementioned disadvantages. The proposed models are fitted to the damage database, containing 178,448 buildings surveyed in the aftermath of the 2011 Japanese tsunami, provided by the Ministry of Land, Infrastructure Transport and Tourism in Japan. In line with the results obtained in previous studies, the fragility curves show that wooden buildings (the dominant construction type in Japan) are the least resistant against tsunami loading. The diagnostics show that taking into account both the building's construction type and the tsunami flow depth is crucial to the quality of the damage estimation and that these two variables do not act independently. In addition, the diagnostics reveal that tsunami flow depth estimates low levels of damage reasonably well; however, it is not the most representative measure of intensity of the tsunami for high damage states (especially structural damage). Further research using disaggregated damage data and additional explanatory variables is required in order to obtain reliable model estimations of building damage probability.

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Section: Introductionmentioning

confidence: 99%

Empirical fragility assessment of buildings affected by the 2011 Great East Japan tsunami using improved statistical models

et al. 2014

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“…Damage levels are typically defined prior to a post-tsunami survey by engineering teams and describe the condition of the affected structure, from zero damage to complete failure, thus forming a damage scale. Such scale is then used in combination with tsunami flow depth measurements (Ruangrassamee et al 2006;Mas et al 2012;Suppasri et al 2012aSuppasri et al , 2013a or results from numerical simulations (Koshimura et al 2009;Suppasri et al 2011Suppasri et al , 2012b in order to classify the surveyed buildings according to their damage state and a corresponding IM. The first column of Table 1 presents the damage scale defined by the Ministry of Land, Infrastructure, Transport and Tourism in Japan (MLIT) for the survey of the buildings affected by the Great East Japan tsunami that struck the country on March, 11, 2011.…”

Section: Introductionmentioning

confidence: 99%

“…Fragility functions are derived by applying regression analysis techniques to the classified observations, using damage state as response variable and the chosen IM (most commonly the tsunami flow depth-e.g., Suppasri et al 2013a, b; in some cases numerically estimated flow velocities, or analytically estimated hydrodynamic forces-e.g., Suppasri et al 2012b) as the explanatory variable. Typically, fragility functions are derived by using linear least squares regression, assuming that the response to be modeled follows a normal or lognormal distribution, and by grouping or re-regrouping the data into bins of tsunami intensity (e.g., Suppasri et al 2011Suppasri et al , 2012a Nevertheless, it was shown by Charvet et al (2013b) and Charvet et al (2014a, b) that considerable uncertainty was introduced in the damage predictions when such methods are used as a tool to analyze building damage data. The results from Charvet et al (2014a) also indicate that highly aggregated databases (i.e., when observations are grouped into a range of tsunami IM, and/or grouped over a wide range of geographical locations) result in a loss of information, potentially yielding variations which cannot be explained by the model.…”

Section: Introductionmentioning

confidence: 99%

A multivariate generalized linear tsunami fragility model for Kesennuma City based on maximum flow depths, velocities and debris impact, with evaluation of predictive accuracy

et al. 2015

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The recent losses caused by the unprecedented 2011 Great East Japan Tsunami disaster have stimulated further research efforts, notably in the mechanisms and probabilistic determination of tsunami-induced damage, in order to provide the necessary information for future risk assessment and mitigation. The stochastic approach typically adopts fragility functions, which express the probability that a building will reach or exceed a predefined damage level usually for one, sometimes several measures of tsunami intensity. However, improvements in the derivation of fragility functions are still needed in order to yield reliable predictions of tsunami damage to buildings. In particular, extensive disaggregated databases, as well as measures of tsunami intensity beyond the commonly used tsunami flow depth should be used to potentially capture variations in the data which have not been explained by previous models. This study proposes to derive fragility functions with additional intensity measures for the city of Kesennuma, which was extensively damaged during the 2011 tsunami and for which a large and disaggregated dataset of building damage is available. In addition to the surveyed tsunami flow depth, the numerically estimated flow velocities as well as a binary indicator of debris impact are included in the model and used simultaneously to estimate building damage probabilities. Following the recently proposed methodology for fragility estimation based on generalized linear models, which overcomes the shortcomings of classic linear regression in fragility analyses, ordinal regression is applied and the reliability of the model estimates is assessed using a proposed penalized accuracy measure, more suitable than the traditional classification error rate for ordinal models. In order to assess the predictive power of the model, penalized accuracy is estimated through a repeated tenfold cross-validation scheme. For the first time, multivariate tsunami fragility functions are derived and represented in the 123Nat Hazards (2015) 79:2073-2099 DOI 10.1007/s11069-015-1947 form of fragility surfaces. The results show that the model is able to predict tsunami damage with satisfactory predictive accuracy and that debris impact is a crucial factor in the determination of building collapse probabilities.

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“…(1) was K = 1.09 with a standard deviation from Eq. (2) of κ = 0.12, which is considered acceptable (Suppasri et al, 2011). Figure 3c shows the tsunami wave form obtained from the synthetic tide gauge.…”

Section: Riskmentioning

confidence: 99%

“…Furthermore, a virtual tide gauge on the Dichato beachfront was defined to obtain arrival times of different tsunami waves. The validation of the numerical simulation was performed using the root mean square error and the parameters K and κ proposed by Aida (1978), cited by Suppasri et al (2011) and given below in Eqs. (1) and (2).…”

Section: Hazardmentioning

confidence: 99%

Risk factors and perceived restoration in a town destroyed by the 2010 Chile tsunami

Martı́nez

Rojas²,

Villagra

et al. 2017

Nat. Hazards Earth Syst. Sci.

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Abstract. A large earthquake and tsunami took place in February 2010, affecting a significant part of the Chilean coast (Maule earthquake, M w of 8.8). Dichato (37 • S), a small town located on Coliumo Bay, was one of the most devastated coastal areas and is currently under reconstruction. Therefore, the objective of this research is to analyze the risk factors that explain the disaster in 2010, as well as perceived restoration 6 years after the event. Numerical modeling of the 2010 Chile tsunami with four nested grids was applied to estimate the hazard. Physical, socioeconomic and educational dimensions of vulnerability were analyzed for pre-and post-disaster conditions. A perceived restoration study was performed to assess the effects of reconstruction on the community. It was focused on exploring the capacity of newly reconstructed neighborhoods to provide restorative experiences in case of disaster. The study was undertaken using the perceived restorativeness scale.The vulnerability variables that best explained the extent of the disaster were housing conditions, low household incomes and limited knowledge about tsunami events, which conditioned inadequate reactions to the emergency. These variables still constitute the same risks as a result of the reconstruction process, establishing that the occurrence of a similar event would result in a similar degree of devastation. For post-earthquake conditions, it was determined that all neighborhoods have the potential to be restorative environments soon after a tsunami. However, some neighborhoods are still located in areas devastated by the 2010 tsunami and again present high vulnerability to future tsunamis.

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Developing tsunami fragility curves based on the satellite remote sensing and the numerical modeling of the 2004 Indian Ocean tsunami in Thailand

Cited by 147 publications

References 6 publications

Empirical fragility assessment of buildings affected by the 2011 Great East Japan tsunami using improved statistical models

Empirical fragility assessment of buildings affected by the 2011 Great East Japan tsunami using improved statistical models

A multivariate generalized linear tsunami fragility model for Kesennuma City based on maximum flow depths, velocities and debris impact, with evaluation of predictive accuracy

Risk factors and perceived restoration in a town destroyed by the 2010 Chile tsunami

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