Simulation of Hurricane Harvey flood event through coupled hydrologic‐hydraulic models: Challenges and next steps

The design code Eurocode 7 relies on semi-probabilistic calculation procedures, through utilization of the soil parameters obtained by in situ and laboratory tests, or by the means of transformation models. To reach a prescribed safety margin, the inherent soil parameter variability is accounted for through the application of partial factors to either soil parameters directly or to the resistance. However, considering several sources of geotechnical uncertainty, including the inherent soil variability, measurement error and transformation uncertainty, full probabilistic analyses should be implemented to directly consider the site-specific variability. This paper presents the procedure of developing fragility curves for levee slope stability and piping as failure mechanisms that lead to larger breaches, where a direct influence of the flood event intensity on the probability of failure is calculated. A range of fragility curve sets is presented, considering the variability of levee material properties and varying durations of the flood event, thus providing crucial insight into the vulnerability of the levee exposed to rising water levels. The procedure is applied to the River Drava levee, a site which has shown a continuous trend of increased water levels in recent years.

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Multi-Agent Deep Reinforcement Learning based Interdependent Critical Infrastructure Simulation Model for Situational Awareness during a Flood Event

IGARSS 2020 - 2020 IEEE International Geoscience and Remote Sensing Symposium ◽

10.1109/igarss39084.2020.9323380 ◽

2020 ◽

Author(s):

Parashuram Shourya Rajulapati ◽

Nivedita Nukavarapu ◽

Surya Durbha

Keyword(s):

Reinforcement Learning ◽

Simulation Model ◽

Situational Awareness ◽

Critical Infrastructure ◽

Flood Event ◽

Multi Agent

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A Conflict between Traditional Flood Measures and Maintaining River Ecosystems? A Case Study Based upon the River Lærdal, Norway

Water ◽

10.3390/w13141884 ◽

2021 ◽

Vol 13 (14) ◽

pp. 1884

Author(s):

Ana Juárez ◽

Knut Alfredsen ◽

Morten Stickler ◽

Ana Adeva-Bustos ◽

Rodrigo Suárez ◽

...

Keyword(s):

Remote Sensing Data ◽

Freshwater Ecosystems ◽

River Channel ◽

Flood Mitigation ◽

Mitigation Measures ◽

Flood Events ◽

Protection Measures ◽

River Ecosystems ◽

Hydraulic Models

Floods are among the most damaging of natural disasters, and flood events are expected to increase in magnitude and frequency with the effects of climate change and changes in land use. As a consequence, much focus has been placed on the engineering of structural flood mitigation measures in rivers. Traditional flood protection measures, such as levees and dredging of the river channel, threaten floodplains and river ecosystems, but during the last decade, sustainable reconciliation of freshwater ecosystems has increased. However, we still find many areas where these traditional measures are proposed, and it is challenging to find tools for evaluation of different measures and quantification of the possible impacts. In this paper, we focus on the river Lærdal in Norway to (i) present the dilemma between traditional flood measures and maintaining river ecosystems and (ii) quantify the efficiency and impact of different solutions based on 2D hydraulic models, remote sensing data, economics, and landscape metrics. Our results show that flood measures may be in serious conflict with environmental protection and legislation to preserve biodiversity and key nature types.

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