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Your search keyword '"Pham, Buu Q."' showing total 21 results
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21 results on '"Pham, Buu Q."'

1. LibERI—A portable and performant multi-GPU accelerated library for electron repulsion integrals via OpenMP offloading and standard language parallelism.

Author

Alkan, Melisa, Pham, Buu Q., Del Angel Cruz, Daniel, Hammond, Jeff R., Barnes, Taylor A., and Gordon, Mark S.

Subjects
*QUANTUM chemistry, *STANDARD language, *INTEGRATED software, *FORTRAN, *HOMOGENEITY
Abstract

A portable and performant graphics processing unit (GPU)-accelerated library for electron repulsion integral (ERI) evaluation, named LibERI, has been developed and implemented via directive-based (e.g., OpenMP and OpenACC) and standard language parallelism (e.g., Fortran DO CONCURRENT). Offloaded ERIs consist of integrals over low and high contraction s, p, and d functions using the rotated-axis and Rys quadrature methods. GPU codes are factorized based on previous developments [Pham et al., J. Chem. Theory Comput. 19(8), 2213–2221 (2023)] with two layers of integral screening and quartet presorting. In this work, the density screening is moved to the GPU to enhance the computational efficacy for large molecular systems. The L-shells in the Pople basis set are also separated into pure S and P shells to increase the ERI homogeneity and reduce atomic operations and the memory footprint. LibERI is compatible with any quantum chemistry drivers supporting the MolSSI Driver Interface. Benchmark calculations of LibERI interfaced with the GAMESS software package were carried out on various GPU architectures and molecular systems. The results show that the LibERI performance is comparable to other state-of-the-art GPU-accelerated codes (e.g., TeraChem and GMSHPC) and, in some cases, outperforms conventionally developed ERI CUDA kernels (e.g., QUICK) while fully maintaining portability. [ABSTRACT FROM AUTHOR]

Published
2024
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2. High-performance strategies for the recent MRSF-TDDFT in GAMESS.

Author

Komarov, Konstantin, Mironov, Vladimir, Lee, Seunghoon, Pham, Buu Q., Gordon, Mark S., and Choi, Cheol Ho

Subjects
TIME-dependent density functional theory, DENSITY matrices, QUANTUM chemistry, EXCITED states, FOULING
Abstract

Multiple ERI (Electron Repulsion Integral) tensor contractions (METC) with several matrices are ubiquitous in quantum chemistry. In response theories, the contraction operation, rather than ERI computations, can be the major bottleneck, as its computational demands are proportional to the multiplicatively combined contributions of the number of excited states and the kernel pre-factors. This paper presents several high-performance strategies for METC. Optimal approaches involve either the data layout reformations of interim density and Fock matrices, the introduction of intermediate ERI quartet buffer, and loop-reordering optimization for a higher cache hit rate. The combined strategies remarkably improve the performance of the MRSF (mixed reference spin flip)-TDDFT (time-dependent density functional theory) by nearly 300%. The results of this study are not limited to the MRSF-TDDFT method and can be applied to other METC scenarios. [ABSTRACT FROM AUTHOR]

Published
2023
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3. Porting fragmentation methods to GPUs using an OpenMP API: Offloading the resolution-of-the-identity second-order Møller–Plesset perturbation method.

Author

Pham, Buu Q., Carrington, Laura, Tiwari, Ananta, Leang, Sarom S., Alkan, Melisa, Bertoni, Colleen, Datta, Dipayan, Sattasathuchana, Tosaporn, Xu, Peng, and Gordon, Mark S.

Subjects
*ATOMIC orbitals, *MATRIX multiplications, *MATRIX inversion, *ELECTRON configuration, *MOLECULAR orbitals, *CENTRAL processing units, *MESOPOROUS silica
Abstract

Using an OpenMP Application Programming Interface, the resolution-of-the-identity second-order Møller–Plesset perturbation (RI-MP2) method has been off-loaded onto graphical processing units (GPUs), both as a standalone method in the GAMESS electronic structure program and as an electron correlation energy component in the effective fragment molecular orbital (EFMO) framework. First, a new scheme has been proposed to maximize data digestion on GPUs that subsequently linearizes data transfer from central processing units (CPUs) to GPUs. Second, the GAMESS Fortran code has been interfaced with GPU numerical libraries (e.g., NVIDIA cuBLAS and cuSOLVER) for efficient matrix operations (e.g., matrix multiplication, matrix decomposition, and matrix inversion). The standalone GPU RI-MP2 code shows an increasing speedup of up to 7.5× using one NVIDIA V100 GPU with one IBM 42-core P9 CPU for calculations on fullerenes of increasing size from 40 to 260 carbon atoms using the 6-31G(d)/cc-pVDZ-RI basis sets. A single Summit node with six V100s can compute the RI-MP2 correlation energy of a cluster of 175 water molecules using the correlation consistent basis sets cc-pVDZ/cc-pVDZ-RI containing 4375 atomic orbitals and 14 700 auxiliary basis functions in ∼0.85 h. In the EFMO framework, the GPU RI-MP2 component shows near linear scaling for a large number of V100s when computing the energy of an 1800-atom mesoporous silica nanoparticle in a bath of 4000 water molecules. The parallel efficiencies of the GPU RI-MP2 component with 2304 and 4608 V100s are 98.0% and 96.1%, respectively. [ABSTRACT FROM AUTHOR]

Published
2023
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4. Multi-level parallelization of quantum-chemical calculations.

Author

Fedorov, Dmitri G. and Pham, Buu Q.

Subjects
*MOLECULAR orbitals, *MOLECULAR dynamics, *QUANTUM chemistry, *PARALLEL programming
Abstract

Strategies for multiple-level parallelizations of quantum-mechanical calculations are discussed, with an emphasis on using groups of workers for performing parallel tasks. These parallel programming models can be used for a variety ab initio quantum chemistry approaches, including the fragment molecular orbital method and replica-exchange molecular dynamics. Strategies for efficient load balancing on problems of increasing granularity are introduced and discussed. A four-level parallelization is developed based on a multi-level hierarchical grouping, and a high parallel efficiency is achieved on the Theta supercomputer using 131 072 OpenMP threads. [ABSTRACT FROM AUTHOR]

Published
2023
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5. The General Atomic and Molecular Electronic Structure System (GAMESS): Novel Methods on Novel Architectures

Author

Zahariev, Federico, primary, Xu, Peng, additional, Westheimer, Bryce M., additional, Webb, Simon, additional, Galvez Vallejo, Jorge, additional, Tiwari, Ananta, additional, Sundriyal, Vaibhav, additional, Sosonkina, Masha, additional, Shen, Jun, additional, Schoendorff, George, additional, Schlinsog, Megan, additional, Sattasathuchana, Tosaporn, additional, Ruedenberg, Klaus, additional, Roskop, Luke B., additional, Rendell, Alistair P., additional, Poole, David, additional, Piecuch, Piotr, additional, Pham, Buu Q., additional, Mironov, Vladimir, additional, Mato, Joani, additional, Leonard, Sam, additional, Leang, Sarom S., additional, Ivanic, Joe, additional, Hayes, Jackson, additional, Harville, Taylor, additional, Gururangan, Karthik, additional, Guidez, Emilie, additional, Gerasimov, Igor S., additional, Friedl, Christian, additional, Ferreras, Katherine N., additional, Elliott, George, additional, Datta, Dipayan, additional, Cruz, Daniel Del Angel, additional, Carrington, Laura, additional, Bertoni, Colleen, additional, Barca, Giuseppe M. J., additional, Alkan, Melisa, additional, and Gordon, Mark S., additional

Published
2023
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12. Recent developments in the general atomic and molecular electronic structure system

Author

Barca, Giuseppe M. J., primary, Bertoni, Colleen, additional, Carrington, Laura, additional, Datta, Dipayan, additional, De Silva, Nuwan, additional, Deustua, J. Emiliano, additional, Fedorov, Dmitri G., additional, Gour, Jeffrey R., additional, Gunina, Anastasia O., additional, Guidez, Emilie, additional, Harville, Taylor, additional, Irle, Stephan, additional, Ivanic, Joe, additional, Kowalski, Karol, additional, Leang, Sarom S., additional, Li, Hui, additional, Li, Wei, additional, Lutz, Jesse J., additional, Magoulas, Ilias, additional, Mato, Joani, additional, Mironov, Vladimir, additional, Nakata, Hiroya, additional, Pham, Buu Q., additional, Piecuch, Piotr, additional, Poole, David, additional, Pruitt, Spencer R., additional, Rendell, Alistair P., additional, Roskop, Luke B., additional, Ruedenberg, Klaus, additional, Sattasathuchana, Tosaporn, additional, Schmidt, Michael W., additional, Shen, Jun, additional, Slipchenko, Lyudmila, additional, Sosonkina, Masha, additional, Sundriyal, Vaibhav, additional, Tiwari, Ananta, additional, Galvez Vallejo, Jorge L., additional, Westheimer, Bryce, additional, Włoch, Marta, additional, Xu, Peng, additional, Zahariev, Federico, additional, and Gordon, Mark S., additional

Published
2020
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19. Compressingthe Four-Index Two-Electron Repulsion Integral Matrix using the Resolution-of-the-Identity Approximation Combined with the Rank Factorization Approximation

Author

Pham, Buu Q. and Gordon, Mark S.

Abstract

The four-index two-electron repulsion integral (4–2ERI) matrix is compressed using the resolution-of-the-identity (RI) approximation combined with the rank factorization approximation (RFA). The 4–2ERI is first approximated by the RI product. Then, the singular value decomposition (SVD) approximation is used to eliminate low-weighted singular vectors. The SVD RI approximation maintains the canonical form of the RI approximation and introduces a tunable compression factor. The characteristics of the SVD RI approximation along with the stochastic RI and natural auxiliary function approximation were numerically examined by applying these methods to the closed-shell second-order Møller–Plesset perturbation theory (MP2). The results show that, while the SVD RI approximation yields large errors for absolute properties (e.g., the correlation energy), it provides accurate relative properties (potential energy surface, binding energy) of the applied ab initio method (e.g., RHF, MP2).

Published
2019
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