Publications

Plimpton, Steven J.; Crozier, Paul C.; Vaughan, Courtenay T.

Abstract not provided.

Doerfler, Douglas W.; Vaughan, Courtenay T.

Abstract not provided.

Bessette, Gregory B.; Bessette, Gregory B.; Vaughan, Courtenay T.; Bell, Raymond L.; Attaway, Stephen W.

A new capability for modeling thin-shell structures within the coupled Euler-Lagrange code, Zapotec, is under development. The new algorithm creates an artificial material interface for the Eulerian portion of the problem by expanding a Lagrangian shell element such that it has an effective thickness that spans one or more Eulerian cells. The algorithm implementation is discussed along with several examples involving blast loading on plates.

Devine, Karen D.; Hendrickson, Bruce A.; Boman, Erik G.; Vaughan, Courtenay T.

The design of general-purpose dynamic load-balancing tools for parallel applications is more challenging than the design of static partitioning tools. Both algorithmic and software engineering issues arise. The authors have addressed many of these issues in the design of the Zoltan dynamic load-balancing library. Zoltan has an object-oriented interface that makes it easy to use and provides separation between the application and the load-balancing algorithms. It contains a suite of dynamic load-balancing algorithms, including both geometric and graph-based algorithms. Its design makes it valuable both as a partitioning tool for a variety of applications and as a research test-bed for new algorithmic development. In this paper, the authors describe Zoltan's design and demonstrate its use in an unstructured-mesh finite element application.