This work presents a vision of future water resources hydrodynamics codes that can fully utilize the strengths of modern high-performance computing. The advances to computing power, formerly driven by the improvement of central processing unit processors, now focus on parallel computing and, in particular, the use of graphics processing units (GPUs). However, this shift to a parallel framework requires refactoring the code to make efficient use of the data as well as changing even the nature of the algorithm that solves the system of equations. These concepts along with other features such as the precision for the computations, dry regions management, and input/output data are analyzed in this paper. A 2D multi-GPU flood code applied to a large-scale test case is used to corroborate our statements and ascertain the new challenges for the next-generation parallel water resources codes.
Abstract. This study evaluates the impact of potential future climate change on flood
regimes, floodplain protection, and electricity infrastructures across the
Conasauga River watershed in the southeastern United States through ensemble
hydrodynamic inundation modeling. The ensemble streamflow scenarios were
simulated by the Distributed Hydrology Soil Vegetation Model (DHSVM) driven
by (1) 1981–2012 Daymet meteorological observations and (2) 11 sets of
downscaled global climate models (GCMs) during the 1966–2005 historical and
2011–2050 future periods. Surface inundation was simulated using a
GPU-accelerated Two-dimensional Runoff Inundation Toolkit for Operational
Needs (TRITON) hydrodynamic model. A total of 9 out of the 11 GCMs exhibit an
increase in the mean ensemble flood inundation areas. Moreover, at the 1 %
annual exceedance probability level, the flood inundation frequency curves
indicate a ∼ 16 km2 increase in floodplain area. The
assessment also shows that even after flood-proofing, four of the
substations could still be affected in the projected future period. The
increase in floodplain area and substation vulnerability highlights the need
to account for climate change in floodplain management. Overall, this study
provides a proof-of-concept demonstration of how the computationally
intensive hydrodynamic inundation modeling can be used to enhance flood
frequency maps and vulnerability assessment under the changing climatic
conditions.
Abstract. This study evaluates the impact of potential future climate change on flood regimes, floodplain protection, and electricity infrastructures across the Conasauga River Watershed in the southeastern United States through ensemble hydrodynamic inundation modeling. The ensemble streamflow scenarios were simulated by the Distributed Hydrology Soil Vegetation Model (DHSVM) driven by (1) 1981–2012 Daymet meteorological observations, and (2) eleven sets of downscaled global climate models (GCMs) during the 1966–2005 historical and 2011–2050 future periods. Surface inundation was simulated using a GPU-accelerated Two-dimensional Runoff Inundation Toolkit for Operational Needs (TRITON) hydrodynamic model. Nine out of the eleven GCMs exhibit an increase in the mean ensemble flood inundation areas. Moreover, at the 1 % annual exceedance probability level, the flood inundation frequency curves indicate a ~ 16 km2 increase in floodplain area. The assessment also shows that even after flood-proofing, four of the substations could still be affected in the projected future period. The increase in floodplain area and substation vulnerability highlights the need to account for climate change in floodplain management. Overall, this study provides a proof-of-concept demonstration of how the computationally intensive hydrodynamic inundation modeling can be used to enhance flood frequency maps and vulnerability assessment under the changing climatic conditions.
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