Publications

Knupp, Patrick K.; Ober, Curtis C.

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Hooper, Russell H.; Ober, Curtis C.; Lorber, Alfred L.

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Knupp, Patrick K.; Ober, Curtis C.

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Knupp, Patrick K.; Ober, Curtis C.

Order-of-accuracy verification is necessary to ensure that software correctly solves a given set of equations. One method to verify the order of accuracy of a code is the method of manufactured solutions. In this study, a manufactured solution has been derived and implemented that allows verification of not only the Euler, Navier-Stokes, and Reynolds-Averaged Navier-Stokes (RANS) equation sets, but also some of their associated boundary conditions (BC's): slip, no-slip (adiabatic and isothermal), and outflow (subsonic, supersonic, and mixed). Order-of-accuracy verification has been performed for the Euler and Navier-Stokes equations and these BC's in a compressible computational fluid dynamics code. All of the results shown are on skewed, non-uniform meshes. RANS results will be presented in a future paper. The observed order of accuracy was lower than the expected order of accuracy in two cases. One of these cases resulted in the identification and correction of a coding mistake in the CHAD gradient correction that was reducing the observed order of accuracy. This mistake would have been undetectable on a Cartesian mesh. During the search for the CHAD gradient correction problem, an unrelated coding mistake was found and corrected. The other case in which the observed order of accuracy was less than expected was a test of the slip BC; although no specific coding or formulation mistakes have yet been identified. After the correction of the identified coding mistakes, all of the aforementioned equation sets and BC's demonstrated the expected (or at least acceptable) order of accuracy except the slip condition.

Robinson, Allen C.; Petney, Sharon P.; Drake, Richard R.; Weirs, Vincent G.; Adams, Brian M.; Vigil, Dena V.; Carpenter, John H.; Garasi, Christopher J.; Wong, Michael K.; Robbins, Joshua R.; Siefert, Christopher S.; Strack, Otto E.; Wills, Ann E.; Trucano, Timothy G.; Bochev, Pavel B.; Summers, Randall M.; Stewart, James R.; Ober, Curtis C.; Rider, William J.; Haill, Thomas A.; Lemke, Raymond W.; Cochrane, Kyle C.; Desjarlais, Michael P.; Love, Edward L.; Voth, Thomas E.; Mosso, Stewart J.; Niederhaus, John H.

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Weirs, Vincent G.; Lemke, Raymond W.; Robinson, Allen C.; Ober, Curtis C.; Banks, Jeffrey W.; Love, Edward L.; Scovazzi, Guglielmo S.; Shadid, John N.; Hanshaw, Heath L.

Abstract not provided.

Bettencourt, Matthew T.; Kramer, Richard M.; Cartwright, Keith C.; Phillips, Edward G.; Ober, Curtis C.; Pawlowski, Roger P.; Swan, Matthew S.; Kalashnikova, Irina; Phipps, Eric T.; Conde, Sidafa C.; Cyr, Eric C.; Ulmer, Craig D.; Kordenbrock, Todd H.; Levy, Scott L.; Templet, Gary J.; Hu, Jonathan J.; Lin, Paul L.; Glusa, Christian A.; Siefert, Christopher S.; Glass, Micheal W.

This report documents the outcome from the ASC ATDM Level 2 Milestone 6358: Assess Status of Next Generation Components and Physics Models in EMPIRE. This Milestone is an assessment of the EMPIRE (ElectroMagnetic Plasma In Realistic Environments) application and three software components. The assessment focuses on the electromagnetic and electrostatic particle-in-cell solu- tions for EMPIRE and its associated solver, time integration, and checkpoint-restart components. This information provides a clear understanding of the current status of the EMPIRE application and will help to guide future work in FY19 in order to ready the application for the ASC ATDM L 1 Milestone in FY20. It is clear from this assessment that performance of the linear solver will have to be a focus in FY19.

Ober, Curtis C.

Abstract not provided.

Ober, Curtis C.; Ober, Curtis C.; Payne, Jeffrey L.; Lorber, Alfred L.

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Jones, Kyle R.; Knox, Hunter A.; van Bloemen Waanders, Bart G.; Ober, Curtis C.; Romero, L.A.

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Ober, Curtis C.

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Ober, Curtis C.

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Ober, Curtis C.

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Pawlowski, Roger P.; Bartlett, Roscoe B.; Bettencourt, Matthew T.; Carleton, James B.; Conde, Sidafa C.; Cyr, Eric C.; Kim, Kyungjoo K.; Mota, Alejandro M.; Perego, Mauro P.; Shadid, John N.; Sjaardema, Gregory D.; Toth, Alexander R.; Bradley, Andrew M.; Spotz, William S.; Ober, Curtis C.; Kalashnikova, Irina

Abstract not provided.

Society of Exploration Geophysicists International Exposition and 80th Annual Meeting 2010, SEG 2010

Smith, Thomas M.; Collis, Samuel S.; Ober, Curtis C.; Overfelt, James R.; Schwaiger, Hans F.

Motivated by the needs of seismic inversion and building on our prior experience for fluid-dynamics systems, we present a high-order discontinuous Galerkin (DG) Runge-Kutta method applied to isotropic, linearized elasto-dynamics. Unlike other DG methods recently presented in the literature, our method allows for inhomogeneous material variations within each element that enables representation of realistic earth models — a feature critical for future use in seismic inversion. Likewise, our method supports curved elements and hybrid meshes that include both simplicial and nonsimplicial elements. We demonstrate the capabilities of this method through a series of numerical experiments including hybrid mesh discretizations of the Marmousi2 model as well as a modified Marmousi2 model with a oscillatory ocean bottom that is exactly captured by our discretization.

Collis, Samuel S.; Ober, Curtis C.; Overfelt, James R.

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Hooper, Russell H.; Ober, Curtis C.

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Collection of Technical Papers - 44th AIAA Aerospace Sciences Meeting

Hooper, Russell H.; Smith, Thomas M.; Ober, Curtis C.

We demonstrate use of a Jacobian-Free Newton-Krylov solver to enable strong thermal coupling at the interface between a solid body and an external compressible fluid. Our method requires only information typically used in loose coupling based on successive substitution and is implemented within a multi-physics framework. We present results for two external flows over thermally conducting solid bodies obtained using both loose and strong coupling strategies. Performance of the two strategies is compared to elucidate both advantages and caveats associated with strong coupling.

van Bloemen Waanders, Bart G.; Ober, Curtis C.

Accurate and timely weather predictions are critical to many aspects of society with a profound impact on our economy, general well-being, and national security. In particular, our ability to forecast severe weather systems is necessary to avoid injuries and fatalities, but also important to minimize infrastructure damage and maximize mitigation strategies. The weather community has developed a range of sophisticated numerical models that are executed at various spatial and temporal scales in an attempt to issue global, regional, and local forecasts in pseudo real time. The accuracy however depends on the time period of the forecast, the nonlinearities of the dynamics, and the target spatial resolution. Significant uncertainties plague these predictions including errors in initial conditions, material properties, data, and model approximations. To address these shortcomings, a continuous data collection occurs at an effort level that is even larger than the modeling process. It has been demonstrated that the accuracy of the predictions depends on the quality of the data and is independent to a certain extent on the sophistication of the numerical models. Data assimilation has become one of the more critical steps in the overall weather prediction business and consequently substantial improvements in the quality of the data would have transformational benefits. This paper describes the use of infrasound inversion technology, enabled through exascale computing, that could potentially achieve orders of magnitude improvement in data quality and therefore transform weather predictions with significant impact on many aspects of our society.

Phillips-Alonge, Kristin E.; Knox, Hunter A.; Ober, Curtis C.; Abbott, Robert A.

Abstract not provided.

Phillips-Alonge, Kristin E.; Knox, Hunter A.; Preston, Leiph A.; Ober, Curtis C.

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Hooper, Russell H.; Ober, Curtis C.; Lorber, Alfred L.

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Hooper, Russell H.; Ober, Curtis C.; Lorber, Alfred L.

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Collis, Samuel S.; Ober, Curtis C.; Overfelt, James R.; Young, Joseph G.

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Ober, Curtis C.; Smith, Thomas M.; van Bloemen Waanders, Bart G.; Collis, Samuel S.

Abstract not provided.