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ORCIDDavid A. Ham
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2020 – today
- 2024
[j16]Daiane I. Dolci
, James R. Maddison, David A. Ham, Guillaume Pallez, Julien Herrmann:
checkpoint_schedules: schedules for incremental checkpointing of adjoint simulations. J. Open Source Softw. 9(96): 6148 (2024)- [i22]David A. Ham, Vaclav Hapla, Matthew G. Knepley, Lawrence Mitchell, Koki Sagiyama:
Efficient N-to-M Checkpointing Algorithm for Finite Element Simulations. CoRR abs/2401.05868 (2024) - [i21]Nacime Bouziani, David A. Ham, Ado Farsi:
Differentiable programming across the PDE and Machine Learning barrier. CoRR abs/2409.06085 (2024) - 2023
- [i20]Nacime Bouziani, David A. Ham:
Physics-driven machine learning models coupling PyTorch and Firedrake. CoRR abs/2303.06871 (2023) - [i19]Reuben W. Nixon-Hill, Daniel Shapero, Colin J. Cotter, David A. Ham:
Consistent Point Data Assimilation in Firedrake and Icepack. CoRR abs/2304.06058 (2023) - [i18]Koki Sagiyama, David A. Ham:
Absorbing boundary conditions for the Helmholtz equation using Gauss-Legendre quadrature reduced integrations. CoRR abs/2308.12255 (2023) - 2022
- [j15]Joseph G. Wallwork, Nicolas Barral, David A. Ham, Matthew D. Piggott:
Goal-Oriented Error Estimation and Mesh Adaptation for Tracer Transport Modelling. Comput. Aided Des. 145: 103187 (2022) - [j14]Justin Crum, Cyrus Cheng, David A. Ham, Lawrence Mitchell, Robert C. Kirby, Joshua A. Levine, Andrew Gillette:
Bringing Trimmed Serendipity Methods to Computational Practice in Firedrake. ACM Trans. Math. Softw. 48(1): 8:1-8:19 (2022) - [i17]Paolo Bientinesi, David A. Ham, Furong Huang, Paul H. J. Kelly, P. Sadayappan, Edward Stow:
Tensor Computations: Applications and Optimization (Dagstuhl Seminar 22101). Dagstuhl Reports 12(3): 1-14 (2022) - 2021
- [j13]Jack D. Betteridge, Patrick E. Farrell, David A. Ham:
Code Generation for Productive, Portable, and Scalable Finite Element Simulation in Firedrake. Comput. Sci. Eng. 23(4): 8-17 (2021) - [i16]David A. Ham:
UFL Dual Spaces, a proposal. CoRR abs/2101.05158 (2021) - [i15]Jack D. Betteridge, Patrick E. Farrell, David A. Ham:
Code generation for productive portable scalable finite element simulation in Firedrake. CoRR abs/2104.08012 (2021) - [i14]Justin Crum, Cyrus Cheng, David A. Ham, Lawrence Mitchell, Robert C. Kirby, Joshua A. Levine, Andrew Gillette:
Bringing Trimmed Serendipity Methods to Computational Practice in Firedrake. CoRR abs/2104.12986 (2021) - [i13]Nacime Bouziani, David A. Ham:
Escaping the abstraction: a foreign function interface for the Unified Form Language [UFL]. CoRR abs/2111.00945 (2021) - 2020
- [j12]Tianjiao Sun, Lawrence Mitchell, Kaushik Kulkarni, Andreas Klöckner, David A. Ham, Paul H. J. Kelly:
A study of vectorization for matrix-free finite element methods. Int. J. High Perform. Comput. Appl. 34(6) (2020) - [i12]Paolo Bientinesi, David A. Ham, Furong Huang, Paul H. J. Kelly, Christian Lengauer, Saday Sadayappan:
Tensor Computations: Applications and Optimization (Dagstuhl Seminar 20111). Dagstuhl Reports 10(3): 58-70 (2020)
2010 – 2019
- 2019
- [i11]Tianjiao Sun, Lawrence Mitchell, Kaushik Kulkarni, Andreas Klöckner, David A. Ham, Paul H. J. Kelly:
A study of vectorization for matrix-free finite element methods. CoRR abs/1903.08243 (2019) - 2018
- [j11]Miklós Homolya, Lawrence Mitchell, Fabio Luporini, David A. Ham:
TSFC: A Structure-Preserving Form Compiler. SIAM J. Sci. Comput. 40(3) (2018) - [i10]Thomas H. Gibson, Lawrence Mitchell, David A. Ham, Colin J. Cotter:
A domain-specific language for the hybridization and static condensation of finite element methods. CoRR abs/1802.00303 (2018) - 2017
- [j10]Florian Rathgeber, David A. Ham, Lawrence Mitchell, Michael Lange, Fabio Luporini, Andrew T. T. McRae, Gheorghe-Teodor Bercea, Graham R. Markall, Paul H. J. Kelly:
Firedrake: Automating the Finite Element Method by Composing Abstractions. ACM Trans. Math. Softw. 43(3): 24:1-24:27 (2017) - [j9]Fabio Luporini, David A. Ham, Paul H. J. Kelly:
An Algorithm for the Optimization of Finite Element Integration Loops. ACM Trans. Math. Softw. 44(1): 3:1-3:26 (2017) - [i9]Miklós Homolya, Lawrence Mitchell, Fabio Luporini, David A. Ham:
TSFC: a structure-preserving form compiler. CoRR abs/1705.03667 (2017) - [i8]Miklós Homolya, Robert C. Kirby, David A. Ham:
Exposing and exploiting structure: optimal code generation for high-order finite element methods. CoRR abs/1711.02473 (2017) - 2016
- [j8]Miklós Homolya, David A. Ham:
A Parallel Edge Orientation Algorithm for Quadrilateral Meshes. SIAM J. Sci. Comput. 38(5) (2016) - [j7]Andrew T. T. McRae, Gheorghe-Teodor Bercea, Lawrence Mitchell, David A. Ham, Colin J. Cotter:
Automated Generation and Symbolic Manipulation of Tensor Product Finite Elements. SIAM J. Sci. Comput. 38(5) (2016) - [i7]Fabio Luporini, David A. Ham, Paul H. J. Kelly:
An algorithm for the optimization of finite element integration loops. CoRR abs/1604.05872 (2016) - [i6]Gheorghe-Teodor Bercea, Andrew T. T. McRae, David A. Ham, Lawrence Mitchell, Florian Rathgeber, Luigi Nardi, Fabio Luporini, Paul H. J. Kelly:
A numbering algorithm for finite element on extruded meshes which avoids the unstructured mesh penalty. CoRR abs/1604.05937 (2016) - 2015
- [j6]Thomas Heinis, David A. Ham:
On-the-Fly Data Synopses: Efficient Data Exploration in the Simulation Sciences. SIGMOD Rec. 44(2): 23-28 (2015) - [i5]Florian Rathgeber, David A. Ham, Lawrence Mitchell, Michael Lange, Fabio Luporini, Andrew T. T. McRae, Gheorghe-Teodor Bercea, Graham R. Markall, Paul H. J. Kelly:
Firedrake: automating the finite element method by composing abstractions. CoRR abs/1501.01809 (2015) - [i4]Miklós Homolya, David A. Ham:
A parallel edge orientation algorithm for quadrilateral meshes. CoRR abs/1505.03357 (2015) - 2014
- [j5]Fabio Luporini, Ana Lucia Varbanescu, Florian Rathgeber, Gheorghe-Teodor Bercea, J. Ramanujam, David A. Ham, Paul H. J. Kelly:
Cross-Loop Optimization of Arithmetic Intensity for Finite Element Local Assembly. ACM Trans. Archit. Code Optim. 11(4): 57:1-57:25 (2014) - [i3]Fabio Luporini, Ana Lucia Varbanescu, Florian Rathgeber, Gheorghe-Teodor Bercea, J. Ramanujam, David A. Ham, Paul H. J. Kelly:
COFFEE: an Optimizing Compiler for Finite Element Local Assembly. CoRR abs/1407.0904 (2014) - [i2]Andrew T. T. McRae, Gheorghe-Teodor Bercea, Lawrence Mitchell, David A. Ham, Colin J. Cotter:
Automated generation and symbolic manipulation of tensor product finite elements. CoRR abs/1411.2940 (2014) - 2013
- [j4]Juan Du, Fangxin Fang, Christopher C. Pain, I. M. Navon, Jiang Zhu, David A. Ham:
POD reduced-order unstructured mesh modeling applied to 2D and 3D fluid flow. Comput. Math. Appl. 65(3): 362-379 (2013) - [j3]Patrick E. Farrell, David A. Ham, Simon W. Funke, Marie E. Rognes:
Automated Derivation of the Adjoint of High-Level Transient Finite Element Programs. SIAM J. Sci. Comput. 35(4) (2013) - [c4]Graham R. Markall, Florian Rathgeber, Lawrence Mitchell, Nicolas Loriant, Carlo Bertolli, David A. Ham, Paul H. J. Kelly:
Performance-Portable Finite Element Assembly Using PyOP2 and FEniCS. ISC 2013: 279-289 - 2012
- [c3]Carlo Bertolli, Adam Betts, Nicolas Loriant, Gihan R. Mudalige, David Radford, David A. Ham, Mike B. Giles, Paul H. J. Kelly:
Compiler Optimizations for Industrial Unstructured Mesh CFD Applications on GPUs. LCPC 2012: 112-126 - [c2]Florian Rathgeber, Graham R. Markall, Lawrence Mitchell, Nicolas Loriant, David A. Ham, Carlo Bertolli, Paul H. J. Kelly:
PyOP2: A High-Level Framework for Performance-Portable Simulations on Unstructured Meshes. SC Companion 2012: 1116-1123 - [i1]Patrick E. Farrell, David A. Ham, Simon W. Funke, Marie E. Rognes:
Automated derivation of the adjoint of high-level transient finite element programs. CoRR abs/1204.5577 (2012) - 2011
- [j2]Colin J. Cotter, David A. Ham:
Numerical wave propagation for the triangular P1DG-P2 finite element pair. J. Comput. Phys. 230(8): 2806-2820 (2011) - 2010
- [c1]Graham R. Markall, David A. Ham, Paul H. J. Kelly:
Towards generating optimised finite element solvers for GPUs from high-level specifications. ICCS 2010: 1815-1823
2000 – 2009
- 2009
- [j1]Colin J. Cotter, David A. Ham, Christopher C. Pain, Sebastian Reich:
LBB stability of a mixed Galerkin finite element pair for fluid flow simulations. J. Comput. Phys. 228(2): 336-348 (2009)
Coauthor Index
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