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We stand with Ukraine

John T. Foster

Orcid: 0000-0002-6955-1156

According to our database¹, John T. Foster authored at least 16 papers between 2014 and 2024.

Collaborative distances:

Dijkstra number² of four.
Erdős number³ of four.

Timeline

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Bibliography

2024

Spatial bagging to integrate spatial correlation into ensemble machine learning.

[BibT_eX]

[DOI]

Fehmi Özbayrak

,

,

Michael J. Pyrcz

Comput. Geosci., 2024

2023

Towards a unified nonlocal, peridynamics framework for the coarse-graining of molecular dynamics data with fractures.

[BibT_eX]

[DOI]

,

,

,

Stewart Silling

,

,

CoRR, 2023

2022

A Petrov-Galerkin method for nonlocal convection-dominated diffusion problems.

[BibT_eX]

[DOI]

,

,

Leszek F. Demkowicz

,

,

J. Comput. Phys., 2022

Multi-Output Physics-Informed Neural Networks for Forward and Inverse PDE Problems with Uncertainties.

[BibT_eX]

[DOI]

,

CoRR, 2022

Machine-learning of nonlocal kernels for anomalous subsurface transport from breakthrough curves.

[BibT_eX]

[DOI]

,

,

Christian Glusa

,

CoRR, 2022

2021

Asymptotically Compatible Reproducing Kernel Collocation and Meshfree Integration for Nonlocal Diffusion.

[BibT_eX]

[DOI]

,

,

Nathaniel Trask

,

SIAM J. Numer. Anal., 2021

Coupling of IGA and Peridynamics for Air-Blast Fluid-Structure Interaction Using an Immersed Approach.

[BibT_eX]

[DOI]

Masoud Behzadinasab

,

Georgios Moutsanidis

,

Nathaniel Trask

,

,

CoRR, 2021

A FETI approach to domain decomposition for meshfree discretizations of nonlocal problems.

[BibT_eX]

[DOI]

,

Christian Glusa

,

,

CoRR, 2021

A machine-learning framework for peridynamic material models with physical constraints.

[BibT_eX]

[DOI]

,

,

CoRR, 2021

2020

A general peridynamics model for multiphase transport of non-Newtonian compressible fluids in porous media.

[BibT_eX]

[DOI]

,

,

,

,

,

Mukul M. Sharma

J. Comput. Phys., 2020

A unified, stable and accurate meshfree framework for peridynamic correspondence modeling. Part II: wave propagation and enforcement of stress boundary conditions.

[BibT_eX]

[DOI]

Masoud Behzadinasab

,

,

CoRR, 2020

Deriving peridynamic influence functions for one-dimensional elastic materials with periodic microstructure.

[BibT_eX]

[DOI]

,

CoRR, 2020

Asymptotically compatible reproducing kernel collocation and meshfree integration for the peridynamic Navier equation.

[BibT_eX]

[DOI]

,

,

Nathaniel A. Trask

,

CoRR, 2020

2019

On the stability of the generalized, finite deformation correspondence model of peridynamics.

[BibT_eX]

[DOI]

Masoud Behzadinasab

,

CoRR, 2019

2016

Onto resolving spurious wave reflection problem with changing nonlocality among various length scales.

[BibT_eX]

[DOI]

Rezwanur Rahman

,

Commun. Nonlinear Sci. Numer. Simul., 2016

2014

A peridynamic formulation of pressure driven convective fluid transport in porous media.

[BibT_eX]

[DOI]

,

,

,

Mukul M. Sharma

J. Comput. Phys., 2014

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