Вычислительные методы и приложения
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A finite-difference scheme for computing axisymmetric plasma oscillations A. V. Popov, E. V. Chizhonkov
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1–13 |
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Error estimation in linear inverse problems with prior information Yu. M. Korolev, A. G. Yagola
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14–18 |
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Application of the integro-interpolation method to the construction of single-step lattice Boltzmann schemes G. V. Krivovichev
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19–27 |
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Optimization of trading strategies by parallel evolutionary computation on graphics processing units O. G. Monakhov
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28–32 |
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Application of heterogeneous computing systems for solving the hydraulic conductivity identification problem A. V. Elesin, A. Sh. Kadyrova
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33–37 |
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Application of heterogeneous computing systems for solving the problem of fluid flow by domain decomposition methods A. V. Tsepaev
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38–43 |
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Peculiarities of exaflops computing in plasma physics V. A. Vshivkov, A. V. Snytnikov
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44–48 |
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A method of restoring the aerosol particle size distribution function on the set of piecewise-convex functions Y. Wang, Y. Zhang, D. V. Luk'yanenko, A. G. Yagola
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49–66 |
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Finite-difference and projection-difference schemes for the unsteady motion of a viscous weakly compressible gas K. A. Zhukov, A. V. Popov
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67–73 |
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Knot insertion and knot removal matrices for nonpolynomial splines A. A. Makarov
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74–86 |
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Application of the subhierarchic method in electrodynamic problems M. Yu. Medvedik
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87–97 |
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A scheme for evaluating the Boltzmann collision integral E. A. Malkov, M. S. Ivanov
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98–106 |
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Load balancing of processors when solving the problems of fluid and gas mechanics by mesh methods K. N. Volkov
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107–129 |
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Three-dimensional simulations of two-phase liquid-vapor systems on GPU using the lattice Boltzmann method A. L. Kupershtokh
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130–138 |
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On approximate open boundary conditions and their performance over long time intervals A. R. Maikov
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139–148 |
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A regularized differential extraproximal method for finding an equilibrium in two-person saddle-point games F. P. Vasil'ev, A. S. Antipin, L. A. Artem'eva
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149–160 |
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An iterative method for computing the flows of a viscoplastic Bingham medium L. V. Muravleva, E. A. Muravleva
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161–171 |
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A numerical method of parameter reconstruction in the Fitz-Hugh–Nagumo and Aliev–Panfilov models I. A. Pavelchak
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172–176 |
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Application of graphic processors for the numerical simulation of viscous incompressible fluid flows in domains of complex geometry by the immersed boundary method E. A. Mortikov
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177–191 |
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Application of projection methods for studying the waveguide and resonance structures with singularities A. I. Erokhin
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192–196 |
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Methods of steepest and hypodifferential descent in one problem of calculus of variations G. Sh. Tamasyan
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197–217 |
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Stationary distribution of product of matrices with random coefficients E. A. Illarionov, D. D. Sokoloff, V. N. Tutubalin
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218–225 |
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Solution of the optimal ship route problem in the framework of the OKEAN geoinformation system B. N. Ivanov
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226–234 |
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Supercomputer technologies in the development of methods for solving inverse problems in ultrasound tomography A. V. Goncharsky, S. Yu. Romanov
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235–238 |
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Speedup of computation when solving the nonhomogeneous diffusion equation by a renormalization method S. S. Makarov, A. V. Isaeva, E. A. Grachev, M. L. Serdobol'skaya
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239–246 |
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On restoration of noisy signals by a regularization method V. A. Morozov
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247–252 |
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Supercomputer modeling of semiconductor quantum nanosystems O. A. Tkachenko, V. A. Tkachenko
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253–262 |
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Efficient numerical methods for the analysis of electromagnetic fields D. Yu. Knyaz'kov
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263–270 |
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Mathematical modeling of radiative electron emission using hybrid supercomputers M. E. Zhukovskii, R. V. Uskov
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271–279 |
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High performance computing in modeling the dynamics and seismicity of tectonic plate systems L. A. Mel'nikova, V. L. Rozenberg
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280–289 |
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Parallel implementation of a three-dimensional hydrodynamic model of shallow water basins on supercomputing systems A. I. Sukhinov, A. E. Chistyakov
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290–297 |
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Программирование
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The making of tools for the development of computational models for the modeling of thermohydraulic processes in nuclear reactors with a liquid-metal heat carrier A. V. Osipov
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1–7 |
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Organization of quantum chemical computations using the Firefly package in a heterogeneous grid environment on the basis of the BOINC platform E. E. Ivashko, N. N. Nikitina
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8–12 |
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Implementation of the lattice Boltzmann method on GPU clusters D. A. Bikulov, D. S. Senin, D. S. Demin, A. V. Dmitriev, N. E. Grachev
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13–19 |
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Application of high performance computing platforms to tomographic particle image velocimetry V. A. Lozhkin, Yu. A. Lozhkin, M. P. Tokarev
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20–27 |
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Parallelization technology for solving multiparameter inverse problems of chemical kinetics I. M. Gubaydullin, Yu. B. Lind, K. F. Koledina
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28–36 |
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Ab initio molecular dynamics: application perspectives of multi-CPU and hybrid supercomputers P. A. Zhilyaev, V. V. Stegailov
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37–45 |