Publications

Rogers, David R.

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Rogers, David R.; Crossno, Patricia J.

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Oldfield, Ron A.; Moreland, Kenneth D.; Fabian, Nathan D.; Rogers, David R.

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Rogers, David R.

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Moreland, Kenneth D.; Rogers, David R.; Fabian, Nathan D.; Oldfield, Ron A.

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Rogers, David R.; Moreland, Kenneth D.; Oldfield, Ron A.; Fabian, Nathan D.

Exascale supercomputing will embody many revolutionary changes in the hardware and software of high-performance computing. A particularly pressing issue is gaining insight into the science behind the exascale computations. Power and I/O speed con- straints will fundamentally change current visualization and analysis work ows. A traditional post-processing work ow involves storing simulation results to disk and later retrieving them for visualization and data analysis. However, at exascale, scien- tists and analysts will need a range of options for moving data to persistent storage, as the current o ine or post-processing pipelines will not be able to capture the data necessary for data analysis of these extreme scale simulations. This Milestone explores two alternate work ows, characterized as in situ and in transit, and compares them. We nd each to have its own merits and faults, and we provide information to help pick the best option for a particular use.

Moreland, Kenneth D.; Crossno, Patricia J.; Rogers, David R.

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Fabian, Nathan D.; Rogers, David R.

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Oldfield, Ron A.; Rogers, David R.; Moreland, Kenneth D.; Fabian, Nathan D.

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Moreland, Kenneth D.; Rogers, David R.

Post-processing and visualization are key components to understanding any simulation. Porting ParaView, a scalable visualization tool, to the Cray XT3 allows our analysts to leverage the same supercomputer they use for simulation to perform post-processing. Visualization tools traditionally rely on a variety of rendering, scripting, and networking resources; the challenge of running ParaView on the Lightweight Kernel is to provide and use the visualization and post-processing features in the absence of many OS resources. We have successfully accomplished this at Sandia National Laboratories and the Pittsburgh Supercomputing Center.

Moreland, Kenneth D.; Rogers, David R.

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Rogers, David R.; Garasi, Christopher J.

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Garasi, Christopher J.; Rogers, David R.

Complex simulations (in particular, those involving multiple coupled physics) cannot be understood solely using geometry-based visualizations. Such visualizations are necessary in interpreting results and gaining insights into kinematics, however they are insufficient when striving to understand why or how something happened, or when investigating a simulation's dynamic evolution. For multiphysics simulations (e.g. those including solid dynamics with thermal conduction, magnetohydrodynamics, and radiation hydrodynamics) complex interactions between physics and material properties take place within the code which must be investigated in other ways. Drawing on the extensive previous work in view coordination, brushing and linking techniques, and powerful visualization libraries, we have developed Prism, an application targeted for a specific analytic need at Sandia National Laboratories. This multiview scientific visualization tool tightly integrates geometric and phase space views of simulation data and material models. Working closely with analysts, we have developed this production tool to promote understanding of complex, multiphysics simulations. We discuss the current implementation of Prism, along with specific examples of results obtained by using the tool.

Rogers, David R.

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Rogers, David R.

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Missert, Nancy A.; Garcia, Robert M.; Nagasubramanian, Ganesan N.; Leung, Kevin L.; Rempe, Susan R.; Rogers, David R.

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Proposed for publication in Coordinated & Multiple Views in Exploratory Visualization, Special Issue of Information Visualization Journal, Vol 2 No. 4, Palgrave/Macmillan.

Crossno, Patricia J.; Crossno, Patricia J.; Rogers, David R.; Brannon, Rebecca M.; Coblentz, David D.

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Crossno, Patricia J.; Crossno, Patricia J.; Rogers, David R.; Brannon, Rebecca M.

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Rogers, David R.

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Rogers, David R.

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Rogers, David R.; Wilson, Andrew T.; Rahal, Nabeel R.

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Rogers, David R.

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Moreland, Kenneth D.; Rogers, David R.

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Rogers, David R.; Brannon, Rebecca M.

An important challenge encountered during post-processing of finite element analyses is the visualizing of three-dimensional fields of real-valued second-order tensors. Namely, as finite element meshes become more complex and detailed, evaluation and presentation of the principal stresses becomes correspondingly problematic. In this paper, we describe techniques used to visualize simulations of perturbed in-situ stress fields associated with hypothetical salt bodies in the Gulf of Mexico. We present an adaptation of the Mohr diagram, a graphical paper and pencil method used by the material mechanics community for estimating coordinate transformations for stress tensors, as a new tensor glyph for dynamically exploring tensor variables within three-dimensional finite element models. This interactive glyph can be used as either a probe or a filter through brushing and linking.

Rogers, David R.

Abstract not provided.