Publications

Cyr, Eric C.; Gulian, Mamikon G.; Patel, Ravi G.; Perego, Mauro P.; Trask, Nathaniel A.

Abstract not provided.

Perego, Mauro P.

Abstract not provided.

Bochev, Pavel B.; Bosler, Peter A.; Kuberry, Paul A.; Perego, Mauro P.; Peterson, Kara J.; Trask, Nathaniel A.

This report summarizes the work performed under a three year LDRD project aiming to develop mathematical and software foundations for compatible meshfree and particle discretizations. We review major technical accomplishments and project metrics such as publications, conference and colloquia presentations and organization of special sessions and minisimposia. The report concludes with a brief summary of ongoing projects and collaborations that utilize the products of this work.

ACM International Conference Proceeding Series

Bogle, Ian; Devine, Karen D.; Perego, Mauro P.; Rajamanickam, Sivasankaran R.; Slota, George M.

We present a new, distributed-memory parallel algorithm for detection of degenerate mesh features that can cause singularities in ice sheet mesh simulations. Identifying and removing mesh features such as disconnected components (icebergs) or hinge vertices (peninsulas of ice detached from the land) can significantly improve the convergence of iterative solvers. Because the ice sheet evolves during the course of a simulation, it is important that the detection algorithm can run in situ with the simulation - - running in parallel and taking a negligible amount of computation time - - so that degenerate features (e.g., calving icebergs) can be detected as they develop. We present a distributed memory, BFS-based label-propagation approach to degenerate feature detection that is efficient enough to be called at each step of an ice sheet simulation, while correctly identifying all degenerate features of an ice sheet mesh. Our method finds all degenerate features in a mesh with 13 million vertices in 0.0561 seconds on 1536 cores in the MPAS Albany Land Ice (MALI) model. Compared to the previously used serial pre-processing approach, we observe a 46,000x speedup for our algorithm, and provide additional capability to do dynamic detection of degenerate features in the simulation.

Bogle, Ian A.; Devine, Karen D.; Perego, Mauro P.; Rajamanickam, Sivasankaran R.; Slota, George M.

Abstract not provided.

Bochev, Pavel B.; Trask, Nathaniel A.; Perego, Mauro P.

Abstract not provided.

Bochev, Pavel B.; Kuberry, Paul A.; Trask, Nathaniel A.; Perego, Mauro P.

Abstract not provided.

Perego, Mauro P.; Bochev, Pavel B.; Kuberry, Paul A.; Trask, Nathaniel A.

Abstract not provided.

Kuberry, Paul A.; Perego, Mauro P.; Trask, Nathaniel A.; Bochev, Pavel B.

Abstract not provided.

Rajamanickam, Sivasankaran R.; Bogle, Ian A.; Hu, Jonathan J.; Devine, Karen D.; Slota, George M.; Perego, Mauro P.; Kim, Kyungjoo K.

Abstract not provided.

Perego, Mauro P.

Abstract not provided.

Trask, Nathaniel A.; Bochev, Pavel B.; Perego, Mauro P.

Abstract not provided.

Kuberry, Paul A.; Perego, Mauro P.; Trask, Nathaniel A.; Bochev, Pavel B.

Abstract not provided.

Perego, Mauro P.; Bochev, Pavel B.; Bosler, Peter A.; Kuberry, Paul A.; Peterson, Kara J.; Trask, Nathaniel A.

Abstract not provided.

Bochev, Pavel B.; Trask, Nathaniel A.; Kuberry, Paul A.; Perego, Mauro P.

Abstract not provided.

Perego, Mauro P.; Barone, Alessandro B.; Hoffman, Matthew J.

Abstract not provided.

Bertagna, Luca B.; Jakeman, John D.; Perego, Mauro P.; Kalashnikova, Irina; Watkins, Jerry E.; Salinger, Andrew G.; Asay-Davis, Xylar A.; Hoffman, Matthew J.; Price, Stephen F.; Zhang, Tong Z.; Stadler, Georg S.

Abstract not provided.

Perego, Mauro P.; Bochev, Pavel B.; Trask, Nathaniel A.; Bosler, Peter A.; Kuberry, Paul A.; Peterson, Kara J.

Abstract not provided.

Perego, Mauro P.; Jakeman, John D.; Severa, William M.; Ruthotto, Lars R.

Abstract not provided.

Geoscientific Model Development

Lipscomb, William H.; Price, Stephen F.; Hoffman, Matthew J.; Leguy, Gunter R.; Bennett, Andrew R.; Bradley, Sarah L.; Evans, Katherine J.; Fyke, Jeremy G.; Kennedy, Joseph H.; Perego, Mauro P.; Ranken, Douglas M.; Sacks, William J.; Salinger, Andrew G.; Vargo, Lauren J.; Worley, Patrick H.

We describe and evaluate version 2.1 of the Community Ice Sheet Model (CISM). CISM is a parallel, 3-D thermomechanical model, written mainly in Fortran, that solves equations for the momentum balance and the thickness and temperature evolution of ice sheets. CISM's velocity solver incorporates a hierarchy of Stokes flow approximations, including shallow-shelf, depth-integrated higher order, and 3-D higher order. CISM also includes a suite of test cases, links to third-party solver libraries, and parameterizations of physical processes such as basal sliding, iceberg calving, and sub-ice-shelf melting. The model has been verified for standard test problems, including the Ice Sheet Model Intercomparison Project for Higher-Order Models (ISMIP-HOM) experiments, and has participated in the initMIP-Greenland initialization experiment. In multimillennial simulations with modern climate forcing on a 4 km grid, CISM reaches a steady state that is broadly consistent with observed flow patterns of the Greenland ice sheet. CISM has been integrated into version 2.0 of the Community Earth System Model, where it is being used for Greenland simulations under past, present, and future climates. The code is open-source with extensive documentation and remains under active development.

Handbook of Nonlocal Continuum Mechanics for Materials and Structures

D'Elia, Marta D.; Bochev, Pavel B.; Littlewood, David J.; Perego, Mauro P.

Nonlocal continuum theories for mechanics can capture strong nonlocal effects due to long-range forces in their governing equations. When these effects cannot be neglected, nonlocal models are more accurate than partial differential equations (PDEs); however, the accuracy comes at the price of a prohibitive computational cost, making local-to-nonlocal (LtN) coupling strategies mandatory. In this chapter, we review the state of the art of LtN methods where the efficiency of PDEs is combined with the accuracy of nonlocal models. Then, we focus on optimization-based coupling strategies that couch the coupling of the models into a control problem where the states are the solutions of the nonlocal and local equations, the objective is to minimize their mismatch on the overlap of the local and nonlocal problem domains, and the virtual controls are the nonlocal volume constraint and the local boundary condition. The strategy is described in the context of nonlocal and local elasticity and illustrated by numerical tests on three-dimensional realistic geometries. Additional numerical tests also prove the consistency of the method via patch tests.

Perego, Mauro P.

Abstract not provided.

Bertagna, Luca B.; Perego, Mauro P.; Hoffman, Matthew J.; Price, Stephen F.

Abstract not provided.

Kuberry, Paul A.; Bosler, Peter A.; Trask, Nathaniel A.; Perego, Mauro P.; Peterson, Kara J.; Bochev, Pavel B.

Abstract not provided.

Bochev, Pavel B.; Trask, Nathaniel A.; Kuberry, Paul A.; Perego, Mauro P.; Peterson, Kara J.; Bosler, Peter A.

Abstract not provided.