Citation: | CHENG Tang-pei, LIU Xing-wei, SHAO Jing-Li, et al. 2016: Review of the algebraic linear methods and parallel implementation in numerical simulation of groundwater flow. Journal of Groundwater Science and Engineering, 4(1): 12-17. |
DONG Yan-hui, LI Guo-ming. 2009. A parallel PCG solver for MODFLOW. Groundwater. 47(6): 845-850.
|
Miller C T, Dawson C N, et al. 2013. Numerical simulation of water resources problems: Models, methods, and trends. Advances in Water Resources, (51): 405-437.
|
JI X H, CHENG T P, et al. 2012. CUDA-based solver for large-scale groundwater flow simulation. Engineering with Computers, 28(1): 13-19.
|
ZHANG K N, WU Y S, Bodvarsson G S. 2003. Parallel computing simulation of fluid flow in the unsaturated zone of Yucca Mountain, Nevada. Journal of Contaminant Hydrology, 62-63(2): 381-399.
|
TANG G P, D'Azevedo E F, et al. 2010. Application of a hybrid MPI/OpenMP approach for parallel groundwater model calibration using multi-core computers. Com?puters & Geosciences, 36(11): 1451- 1460.
|
Harbaugh A W. 2005. MODFLOW-2005, the US geological survey modular groundwater model: The groundwater flow process. Reston, VA, USA: US Department of the Interior, US Geological Survey.
|
Knoll D A, Keyes D E. 2004. Jacobian-free Newton-Krylov methods: A survey of approaches and applications. Journal of Computational Physics. 193(2): 357-397.
|
Saad Y. 2003. Iterative methods for sparse linear systems. Philadelphia: Society for Industrial and Applied Mathematics.
|
Hwang H T, Park Y J, et al. 2014. A parallel computational framework to solve flow and transport in integrated surface-subsurface hydrologic systems. Environmental Model?ling & Software, 61: 39-58.
|
Hughes J D, White J T. 2013. Use of general purpose graphics processing units with MODFLOW. Groundwater, 51(6): 833-846.
|
Nakajima K. 2011. Parallel multigrid solvers using openmp/mpi hybrid programming models on multi-core/multi-socket clusters. In: High Performance Computing for Computational Science-Vecpar 2010. Berlin: Springer.
|
Le P V V, Kumar P, et al. 2015. GPU-based high-performance computing for integrated surface-sub-surface flow modeling. Environ?mental Modelling & Software, 73: 1-13.
|
Hammond G E, Lichtner P C, Mills R T. 2014. Evaluating the performance of parallel subsurface simulators: An illustrative example with PFLOTRAN. Water Resources Research, 50(1): 208-228.
|
CHENG Tang-pei, SHAO Jing-li, et al. 2014b. Parallel simulation of groundwater flow in the North China Plain. Journal of Earth Science, 25(6): 1059-1066.
|
Dongarra J J, Foster I, et al. 2003. Sourcebook of parallel computing. San Francisco: Morgan Kaufmann Publishers.
|
CHENG Tang-pei, MO Ze-yao, SHAO Jing-li. 2014a. Accelerating groundwater flow simulation in MODFLOW using JASMIN- Based parallel computing. Groundwater, 52(2): 194-205.
|
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JGSE-ScholarOne Manuscript Launched on June 1, 2024.