Publications

Pawlowski, Roger P.; Phipps, Eric T.; Trott, Christian R.; Cyr, Eric C.; Shadid, John N.

Abstract not provided.

Patel, Ravi G.; Trask, Nathaniel A.; Wood, Mitchell A.; Cyr, Eric C.

Abstract not provided.

Miller, Sean M.; Roberts, Nathan V.; Cyr, Eric C.

Abstract not provided.

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

Abstract not provided.

Cyr, Eric C.; Guenther, S.; Ruthotto, Lars R.; Schroder, J.; Gauger, N.; Ridzal, Denis R.

Abstract not provided.

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

Abstract not provided.

Journal of Computational Physics

Mabuza, Sibusiso M.; Shadid, John N.; Cyr, Eric C.; Pawlowski, Roger P.; Kuzmin, Dmitri

In this work, a stabilized continuous Galerkin (CG) method for magnetohydrodynamics (MHD) is presented. Ideal, compressible inviscid MHD equations are discretized in space on unstructured meshes using piecewise linear or bilinear finite element bases to get a semi-discrete scheme. Stabilization is then introduced to the semi-discrete method in a strategy that follows the algebraic flux correction paradigm. This involves adding some artificial diffusion to the high order, semi-discrete method and mass lumping in the time derivative term. The result is a low order method that provides local extremum diminishing properties for hyperbolic systems. The difference between the low order method and the high order method is scaled element-wise using a limiter and added to the low order scheme. The limiter is solution dependent and computed via an iterative linearity preserving nodal variation limiting strategy. The stabilization also involves an optional consistent background high order dissipation that reduces phase errors. The resulting stabilized scheme is a semi-discrete method that can be applied to inviscid shock MHD problems and may be even extended to resistive and viscous MHD problems. To satisfy the divergence free constraint of the MHD equations, we add parabolic divergence cleaning to the system. Various time integration methods can be used to discretize the scheme in time. We demonstrate the robustness of the scheme by solving several shock MHD problems.

Arxiv

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

Abstract not provided.

Cyr, Eric C.; Guenther, Stefanie G.; Ruthotto, Lars R.; Schroder, Jacob B.; Gauger, Nico R.

Abstract not provided.

Miller, Sean M.; Cyr, Eric C.; Phillips, Edward G.; Pawlowski, Roger P.; Beckwith, Kristian B.; Bettencourt, Matthew T.; Cartwright, Keith C.; Shields, Sidney S.

Abstract not provided.

SIAM Journal on Mathematics of Data Science

Guenther, Stefanie G.; Ruthotto, Lars R.; Schroder, Jacob B.; Cyr, Eric C.; Gauger, Nicolas R.

Residual neural networks (ResNets) are a promising class of deep neural networks that have shown excellent performance for a number of learning tasks, e.g., image classification and recognition. Mathematically, ResNet architectures can be interpreted as forward Euler discretizations of a nonlinear initial value problem whose time-dependent control variables represent the weights of the neural network. Hence, training a ResNet can be cast as an optimal control problem of the associated dynamical system. For similar time-dependent optimal control problems arising in engineering applications, parallel-in-time methods have shown notable improvements in scalability. This paper demonstrates the use of those techniques for efficient and effective training of ResNets. The proposed algorithms replace the classical (sequential) forward and backward propagation through the network layers with a parallel nonlinear multigrid iteration applied to the layer domain. This adds a new dimension of parallelism across layers that is attractive when training very deep networks. From this basic idea, we derive multiple layer-parallel methods. The most efficient version employs a simultaneous optimization approach where updates to the network parameters are based on inexact gradient information in order to speed up the training process. Finally, using numerical examples from supervised classification, we demonstrate that the new approach achieves a training performance similar to that of traditional methods, but enables layer-parallelism and thus provides speedup over layer-serial methods through greater concurrency.

Cyr, Eric C.

Abstract not provided.

Cyr, Eric C.; Guenther, Stefanie G.; Ruthotto, Lars R.; Schroder, Jacob B.; Gauger, Nico R.

Abstract not provided.

Lecture Notes in Computational Science and Engineering

Phillips, Edward G.; Shadid, John N.; Cyr, Eric C.; Miller, Sean M.

Recent work has demonstrated that block preconditioning can scalably accelerate the performance of iterative solvers applied to linear systems arising in implicit multiphysics PDE simulations. The idea of block preconditioning is to decompose the system matrix into physical sub-blocks and apply individual specialized scalable solvers to each sub-block. It can be advantageous to block into simpler segregated physics systems or to block by discretization type. This strategy is particularly amenable to multiphysics systems in which existing solvers, such as multilevel methods, can be leveraged for component physics and to problems with disparate discretizations in which scalable monolithic solvers are rare. This work extends our recent work on scalable block preconditioning methods for structure-preserving discretizatons of the Maxwell equations and our previous work in MHD system solvers to the context of multifluid electromagnetic plasma systems. We argue how a block preconditioner can address both the disparate discretization, as well as strongly-coupled off-diagonal physics that produces fast time-scales (e.g. plasma and cyclotron frequencies). We propose a block preconditioner for plasma systems that allows reuse of existing multigrid solvers for different degrees of freedom while capturing important couplings, and demonstrate the algorithmic scalability of this approach at time-scales of interest.

Journal of Computational Physics

Chung, Seung W.; Bond, Stephen D.; Cyr, Eric C.; Freund, Jonathan B.

Particle-in-cell (PIC) simulation methods are attractive for representing species distribution functions in plasmas. However, as a model, they introduce uncertain parameters, and for quantifying their prediction uncertainty it is useful to be able to assess the sensitivity of a quantity-of-interest (QoI) to these parameters. Such sensitivity information is likewise useful for optimization. However, computing sensitivity for PIC methods is challenging due to the chaotic particle dynamics, and sensitivity techniques remain underdeveloped compared to those for Eulerian discretizations. This challenge is examined from a dual particle–continuum perspective that motivates a new sensitivity discretization. Two routes to sensitivity computation are presented and compared: a direct fully-Lagrangian particle-exact approach provides sensitivities of each particle trajectory, and a new particle-pdf discretization, which is formulated from a continuum perspective but discretized by particles to take the advantages of the same type of Lagrangian particle description leveraged by PIC methods. Since the sensitivity particles in this approach are only indirectly linked to the plasma-PIC particles, they can be positioned and weighted independently for efficiency and accuracy. The corresponding numerical algorithms are presented in mathematical detail. The advantage of the particle-pdf approach in avoiding the spurious chaotic sensitivity of the particle-exact approach is demonstrated for Debye shielding and sheath configurations. In essence, the continuum perspective makes implicit the distinctness of the particles, which circumvents the Lyapunov instability of the N-body PIC system. The cost of the particle-pdf approach is comparable to the baseline PIC simulation.

Cyr, Eric C.; Shadid, John N.; Tuminaro, Raymond S.; Chacon, Luis C.; Pawlowski, Roger P.; Phillips, Edward G.; Miller, Sean M.

Abstract not provided.

Roberts, Nathan V.; Henneking, Stefan K.; Miller, Sean M.; Cyr, Eric C.

Abstract not provided.

Cyr, Eric C.; Guenther, Stefanie G.; Schroder, Jacob B.

Abstract not provided.

Cyr, Eric C.; Gulian, Mamikon G.; Patel, Ravi G.; Perego, Mauro P.; Trask, Nathaniel A.; Ridzal, Denis R.; Guenther, Stefanie G.; Ruthotto, Lars R.; Schroder, Jacob B.; Gauger, Nico R.

Abstract not provided.

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

Abstract not provided.

Miller, Sean M.; Cyr, Eric C.; Bettencourt, Matthew T.; Gardiner, Thomas A.; Beckwith, Kristian B.; Hamlin, Nathaniel D.; Shields, Sidney S.

Abstract not provided.

Cyr, Eric C.; Miller, Sean M.; Pawlowski, Roger P.; Phillips, Edward G.; Beckwith, Kristian B.; Bettencourt, Matthew T.; Cartwright, Keith C.; Kramer, Richard M.; Roberts, Nathan V.; Shadid, John N.; Shields, Sidney S.

Abstract not provided.

Shields, Sidney S.; Cartwright, Keith C.; Miller, Sean M.; Pointon, Timothy D.; Cyr, Eric C.; Beckwith, Kristian B.

Abstract not provided.

Conde, Sidafa C.; Mabuza, Sibu M.; Shadid, John N.; Cyr, Eric C.; Smith, Thomas M.; Pawlowski, Roger P.

Abstract not provided.

Cyr, Eric C.; Miller, Sean M.; Phillips, Edward G.; Beckwith, Kristian B.; Bettencourt, Matthew T.; Cartwright, Keith C.; Kramer, Richard M.; Pawlowski, Roger P.; Roberts, Nathan V.; Shadid, John N.; Shields, Sidney S.

Abstract not provided.