Estimating insured residential losses from large flood scenarios on the Tone River, Japan – a data integration approach

Okada, Tetsuya; McAneney, K. John; Chen, K.

doi:10.5194/nhess-11-3373-2011

Cited by 20 publications

(12 citation statements)

References 14 publications

(13 reference statements)

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“…Research on flood loss modeling, especially in the agricultural sector, has been conducted in many countries on a regional scale. Simulation results strongly depend on affected crops, which need to be predicted accurately [31]- [35].…”

Section: Introductionmentioning

confidence: 99%

Rapid Damage Assessment of Rice Crop After Large-Scale Flood in the Cambodian Floodplain Using Temporal Spatial Data

Kwak

Shrestha

Yorozuya

et al. 2015

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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The objective of this study was to estimate rice crop damage over the entire Cambodia during a large flood event from July to November 2011. An integrated approach was applied to detect and monitor flood areas with flood depth and duration for near real-time rice crop damage estimation in 2011 by using MODIS time-series imagery. The combined data consists of developed MLSWI, EVI from MODIS, new FID from DEM, land use, and simplified empirical damage curves. These data are expected to play an important role in emergency response efforts and rapid risk assessment for high-risk flood areas in the Cambodian floodplain. A rice crop damage map will be generated, showing areas with different damage levels based on flood duration and floodwater depth, including 25% (8 days, below 1.5 m), 50% (8 days, over 1.5 m; 16 days, below 1.5 m), and 100% (16 days, over 1.5 m). The resulting map was validated and shows about 80% consistency with the government census based on field-scale investigation and survey. Index Terms-Cambodian floodplain, damage curves, large flood, MODIS, rice crop damage.

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Section: Introductionmentioning

confidence: 99%

Rapid Damage Assessment of Rice Crop After Large-Scale Flood in the Cambodian Floodplain Using Temporal Spatial Data

Kwak

Shrestha

Yorozuya

et al. 2015

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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“…analysis requires that a threshold of water depth is set to distinguish flood inundation from the temporal ponding of rain water. In this study we used 0.5 m as the threshold to follow the previous study (Sayama et al, 2012(Sayama et al, , 2015 since a water level deeper than that may cause severe damages with above-floor flooding (Okada et al, 2011). The other possible reason for the underestimation is that in actual situations, in areas with relatively shallow water flooding, water tends to be stagnant due to roads and paddy field ridges, while in the model, water moves more smoothly because of the resolution; and therefore the model tends to underestimate the flood inundation extent in fringed areas (Sayama et al, 2015).…”

Section: Flood Inundationmentioning

confidence: 99%

Hydrologic sensitivity of flood runoff and inundation: 2011 Thailand floods in the Chao Phraya River basin

Sayama

Tatebe

Iwami

et al. 2015

Nat. Hazards Earth Syst. Sci.

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Abstract. The Thailand floods in 2011 caused unprecedented economic damage in the Chao Phraya River basin. To diagnose the flood hazard characteristics, this study analyses the hydrologic sensitivity of flood runoff and inundation to rainfall. The motivation is to address why the seemingly insignificant monsoon rainfall, or 1.2 times more rainfall than for past large floods, including the ones in 1995 and 2006, resulted in such devastating flooding. To quantify the hydrologic sensitivity, this study simulated longterm rainfall-runoff and inundation for the entire river basin (160 000 km 2 ). The simulation suggested that the flood inundation volume was 1.6 times more in 2011 than for the past flood events. Furthermore, the elasticity index suggested that a 1 % increase in rainfall causes a 2.3 % increase in runoff and a 4.2 % increase in flood inundation. This study highlights the importance of sensitivity quantification for a better understanding of flood hazard characteristics; the presented basin-wide rainfall-runoff-inundation simulation was an effective approach to analyse the sensitivity of flood runoff and inundation at the river basin scale.

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“…This study selected the threshold value 0.5 m of water depth to distinguish between the flood and non-flood areas. Previous studies [21,22,36] have chosen this threshold value since water level is related to severe flood damage in the floodplain where the agricultural area is dominant land use type [37]. According to the performance indices of the spatial inundation extent in Table 3, the RRI model simulated the flood extent with a good agreement of 84% accuracy (i.e.…”

Section: Rri Model Calibration and Validationmentioning

confidence: 99%

Comparison of gridded precipitation datasets for rainfall-runoff and inundation modeling in the Mekong River Basin

Try

Tanaka

et al. 2020

PLoS ONE

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Precipitation, as a primary hydrological variable in the water cycle plays an important role in hydrological modeling. The reliability of hydrological modeling is highly related to the quality of precipitation data. Accurate long-term gauged precipitation in the Mekong River Basin, however, is limited. Therefore, the main objective of this study is to assess the performances of various gridded precipitation datasets in rainfall-runoff and flood-inundation modeling of the whole basin. Firstly, the performance of the Rainfall-Runoff-Inundation (RRI) model in this basin was evaluated using the gauged rainfall. The calibration (2000-2003) and validation (2004-2007) results indicated that the RRI model had acceptable performance in the Mekong River Basin. In addition, five gridded precipitation datasets including APHRODITE, GPCC, PERSIANN-CDR, GSMaP (RNL), and TRMM (3B42V7) from 2000 to 2007 were applied as the input to the calibrated model. The results of the simulated river discharge indicated that TRMM, GPCC, and APHRODITE performed better than other datasets. The statistical index of the annual maximum inundated area indicated similar conclusions. Thus, APHRODITE, TRMM, and GPCC precipitation datasets were considered suitable for rainfall-runoff and flood inundation modeling in the Mekong River Basin. This study provides useful guidance for the application of gridded precipitation in hydrological modeling in the Mekong River basin.

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Estimating insured residential losses from large flood scenarios on the Tone River, Japan – a data integration approach

Cited by 20 publications

References 14 publications

Rapid Damage Assessment of Rice Crop After Large-Scale Flood in the Cambodian Floodplain Using Temporal Spatial Data

Rapid Damage Assessment of Rice Crop After Large-Scale Flood in the Cambodian Floodplain Using Temporal Spatial Data

Hydrologic sensitivity of flood runoff and inundation: 2011 Thailand floods in the Chao Phraya River basin

Comparison of gridded precipitation datasets for rainfall-runoff and inundation modeling in the Mekong River Basin

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