The Uintah software suite is a set of libraries and applications for simulating and analyzing complex chemical and physical reactions. These reactions are modeled by solving partial differential equations on structured adaptive grids using hundreds to thousands of processors (though smaller simulations may also be run on a scientist’s desktop computer). Key software applications have been developed for exploring the fine details of metal containers (encompassing energetic materials) embedded in large hydrocarbon fires. Uintah’s underlying technologies have led to novel techniques for understanding large pool eddy fires as well as new methods for simulating fluid-structure interactions. The software is general purpose in nature and the breadth of simulation domains continues to grow beyond the original focus of the C-SAFE initiative.

References in zbMATH (referenced in 21 articles , 1 standard article )

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  1. Church, Jon Matteo; Guo, Zhenlin; Jimack, Peter K.; Madzvamuse, Anotida; Promislow, Keith; Wetton, Brian; Wise, Steven M.; Yang, Fengwei: High accuracy benchmark problems for Allen-Cahn and Cahn-Hilliard dynamics (2019)
  2. Leavy, R. B.; Guilkey, J. E.; Phung, B. R.; Spear, A. D.; Brannon, R. M.: A convected-particle tetrahedron interpolation technique in the material-point method for the mesoscale modeling of ceramics (2019)
  3. Weinzierl, Tobias: The Peano software -- parallel, automaton-based, dynamically adaptive grid traversals (2019)
  4. Kidder, Lawrence E.; Field, Scott E.; Foucart, Francois; Schnetter, Erik; Teukolsky, Saul A.; Bohn, Andy; Deppe, Nils; Diener, Peter; Hébert, François; Lippuner, Jonas; Miller, Jonah; Ott, Christian D.; Scheel, Mark A.; Vincent, Trevor: SpECTRE: A task-based discontinuous Galerkin code for relativistic astrophysics (2017)
  5. Anshu Dubey, Ann Almgren, John Bell, Martin Berzins, Steve Brandt, Greg Bryan, Phillip Colella, Daniel Graves, Michael Lijewski, Frank Loffler, Brian O’Shea, Erik Schnetter, Brian Van Straalen, Klaus Weide: A Survey of High Level Frameworks in Block-Structured Adaptive Mesh Refinement Packages (2016) arXiv
  6. Berzins, Martin; Beckvermit, Jacqueline; Harman, Todd; Bezdjian, Andrew; Humphrey, Alan; Meng, Qingyu; Schmidt, John; Wight, Charles: Extending the Uintah framework through the petascale modeling of detonation in arrays of high explosive devices (2016)
  7. Homel, Michael A.; Brannon, Rebecca M.; Guilkey, James: Controlling the onset of numerical fracture in parallelized implementations of the material point method (MPM) with convective particle domain interpolation (CPDI) domain scaling (2016)
  8. Tang, Yu-Hang; Kudo, Shuhei; Bian, Xin; Li, Zhen; Karniadakis, George Em: Multiscale universal interface: a concurrent framework for coupling heterogeneous solvers (2015)
  9. Weinbub, Josef; Rupp, Karl; Selberherr, Siegfried: Highly flexible and reusable finite element simulations with ViennaX (2014)
  10. Burghardt, Jeff; Brannon, R.; Guilkey, J.: A nonlocal plasticity formulation for the material point method (2012)
  11. Chen, L.; Lee, J. H.; Chen, C.-F.: On the modeling of surface tension and its applications by the generalized interpolation material point method (2012)
  12. Notz, Patrick K.; Pawlowski, Roger P.; Sutherland, James C.: Graph-based software design for managing complexity and enabling concurrency in multiphysics PDE software (2012)
  13. Ray, J.; Armstrong, R.; Safta, C.; Debusschere, B. J.; Allan, B. A.; Najm, H. N.: Computational frameworks for advanced combustion simulations (2011)
  14. Steffen, Michael; Kirby, Robert M.; Berzins, Martin: Analysis and reduction of quadrature errors in the material point method (MPM) (2008)
  15. McInnes, Lois Curfman; Allan, Benjamin A.; Armstrong, Robert; Benson, Steven J.; Bernholdt, David E.; Dahlgren, Tamara L.; Diachin, Lori Freitag; Krishnan, Manojkumar; Kohl, James A.; Larson, J. Walter; Lefantzi, Sophia; Nieplocha, Jarek; Norris, Boyana; Parker, Steven G.; Ray, Jaideep; Zhou, Shujia: Parallel PDE-based simulations using the common component architecture (2006)
  16. Davison de St. Germain, J.; Morris, Alan; Parker, Steven G.; Malony, Allen D.; Shende, Sameer: Performance analysis integration in the Uintah software development cycle (2003)
  17. Allan, Benjamin A.; Armstrong, Robert C.; Wolfe, Alicia P.; Ray, Jaideep; Bernholdt, David E.; Kohl, James A.: The CCA core specification in a distributed memory SPMD framework (2002)
  18. Davison de St. Germain, J.; Morris, Alan; Parker, Steven G.; Malony, Allen D.; Shende, Sameer: Integrating performance analysis in the Uintah software development cycle (2002)
  19. Johnson, Chris; Parker, Steve; Weinstein, David; Heffernan, Sean: Component-based, problem-solving environments for large-scale scientific computing (2002)
  20. Parker, S. G.: A component-based architecture for parallel multi-physics PDE simulation (2002)

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