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ExaWind: Exascale Predictive Wind Plant Flow Physics Modeling

Sprague, Michael; Ananthan, Shreyas; Binyahib, Roba; Brazell, Michael; De Frahan, Marc H.; King, Ryan A.; Mullowney, Paul; Rood, Jon; Sharma, Ashesh; Thomas, Stephen A.; Vijayakumar, Ganesh; Crozier, Paul; Berger-Vergiat, Luc; Cheung, Lawrence; Dement, David C.; Bays, Nathan R.; Glaze, David J.; Hu, Jonathan J.; Knaus, Robert C.; Lee, Dong H.; Matula, Neil R.; Okusanya, Tolulope O.; Overfelt, James R.; Rajamanickam, Sivasankaran; Sakievich, Philip; Smith, Timothy A.; Vo, Johnathan; Williams, Alan B.; Yamazaki, Ichitaro; Turner, William J.; Prokopenko, Andrey; Wilson, Robert V.; Moser, Robert; Melvin, Jeremy; Sitaraman, Jay

Abstract not provided.

Demonstration and performance testing of extreme-resolution simulations with static meshes on Summit (CPU & GPU) for a parked-turbine configuration and an actuator-line (mid-fidelity model) wind farm configuration (ECP-Q4 FY2020 Milestone Report)

Anathan, Sheryas; Williams, Alan B.; Overfelt, James R.; Vo, Johnathan; Sakievich, Philip; Smith, Timothy A.; Hu, Jonathan J.; Berger-Vergiat, Luc; Mullowney, Paul; Thomas, Stephen; Henry De Frahan, Marc; Melvin, Jeremy; Moser, Robert; Brazell, Michael; Sprague, Michael A.

The goal of the ExaWind project is to enable predictive simulations of wind farms comprised of many megawatt-scale turbines situated in complex terrain. Predictive simulations will require computational fluid dynamics (CFD) simulations for which the mesh resolves the geometry of the turbines and captures the rotation and large deflections of blades. Whereas such simulations for a single turbine are arguably petascale class, multi-turbine wind farm simulations will require exascale-class resources. The primary physics codes in the ExaWind simulation environment are Nalu-Wind, an unstructured-grid solver for the acoustically incompressible Navier-Stokes equations, AMR-Wind, a block-structured-grid solver with adaptive mesh refinement capabilities, and OpenFAST, a wind-turbine structural dynamics solver. The Nalu-Wind model consists of the mass-continuity Poisson-type equation for pressure and Helmholtz-type equations for transport of momentum and other scalars. For such modeling approaches, simulation times are dominated by linear-system setup and solution for the continuity and momentum systems. For the ExaWind challenge problem, the moving meshes greatly affect overall solver costs as reinitialization of matrices and recomputation of preconditioners is required at every time step. The choice of overset-mesh methodology to model the moving and non-moving parts of the computational domain introduces constraint equations in the elliptic pressure-Poisson solver. The presence of constraints greatly affects the performance of algebraic multigrid preconditioners.

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ExaWind: Exascale Predictive Wind Plant Flow Physics Modeling

Sprague, M.; Ananthan, S.; Brazell, M.; Glaws, A.; De Frahan, M.; King, R.; Natarajan, M.; Rood, J.; Sharma, A.; Sirydowicz, K.; Thomas, S.; Vijaykumar, G.; Yellapantula, S.; Crozier, Paul; Berger-Vergiat, Luc; Cheung, Lawrence; Glaze, David J.; Hu, Jonathan J.; Knaus, Robert C.; Lee, Dong H.; Okusanya, Tolulope O.; Overfelt, James R.; Rajamanickam, Sivasankaran; Sakievich, Philip; Smith, Timothy A.; Vo, Johnathan; Williams, Alan B.; Yamazaki, Ichitaro; Turner, J.; Prokopenko, A.; Wilson, R.; Moser, R.; Melvin, J.; Sitaraman, J.

Abstract not provided.

High fidelity surrogate modeling of fuel dissolution for probabilistic assessment of repository performance

International High-Level Radioactive Waste Management 2019, IHLRWM 2019

Mariner, Paul E.; Swiler, Laura P.; Seidl, D.T.; Debusschere, Bert J.; Vo, Johnathan; Frederick, Jennifer M.

Two surrogate models are under development to rapidly emulate the effects of the Fuel Matrix Degradation (FMD) model in GDSA Framework. One is a polynomial regression surrogate with linear and quadratic fits, and the other is a k-Nearest Neighbors regressor (kNNr) method that operates on a lookup table. Direct coupling of the FMD model to GDSA Framework is too computationally expensive. Preliminary results indicate these surrogate models will enable GDSA Framework to rapidly simulate spent fuel dissolution for each individual breached spent fuel waste package in a probabilistic repository simulation. This capability will allow uncertainties in spent fuel dissolution to be propagated and sensitivities in FMD inputs to be quantified and ranked against other inputs.

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Results 26–33 of 33
Results 26–33 of 33
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