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Your search keyword '"Hu, Xiangyu Y."' showing total 35 results
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35 results on '"Hu, Xiangyu Y."'

1. A species-clustered ODE solver for large-scale chemical kinetics using detailed mechanisms

Author

Wang, Jian-Hang, Pan, Shucheng, Hu, Xiangyu Y., and Adams, Nikolaus A.

Subjects
Physics - Computational Physics
Abstract

In this study, a species-clustered ordinary differential equations (ODE) solver for chemical kinetics with large detailed mechanisms based on operator-splitting is presented. The ODE system is split into clusters of species by using graph partition methods which has been intensively studied in areas of model reduction, parameterization and coarse-graining, etc. , such as diffusion maps based on the concept of Markov random walk. Definition of the weight (similarity) matrix is application-driven and according to chemical kinetics. Each cluster of species is then integrated by VODE, an implicit solver which is intractable and costly for large systems of many species and reactions. Expected speedup in computational efficiency is observed by numerical experiments on three zero-dimensional (0D) auto-ignition problems, considering the detailed hydrocarbon/air combustion mechanisms in varying scales, from 53 species with 325 reactions of methane to 2115 species with 8157 reactions of n-hexadecane., Comment: 28 pages and 14 figures

Published
2018
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2. A Lagrangian Inertial Centroidal Voronoi Particle method for dynamic load balancing in particle-based simulations

Author

Ji, Zhe, Fu, Lin, Hu, Xiangyu Y., and Adams, Nikolaus A.

Subjects
Physics - Computational Physics
Abstract

In this paper we develop a Lagrangian Inertial Centroidal Voronoi Particle (LICVP) method to extend the original CVP method \cite{fu2017physics} to dynamic load balancing in particle-based simulations. Two new concepts are proposed to address the additional problems encountered in repartitioning the system. First, a background velocity is introduced to transport Voronoi particle according to the local fluid field, which facilitates data reuse and lower data redistribution cost during rebalancing. Second, in order to handle problems with skew-aligned computational load and large void space, we develop an inertial-based partitioning strategy, where the inertial matrix is utilized to characterize the load distribution, and to confine the motion of Voronoi particles dynamically adapting to the physical simulation. Intensive numerical tests in fluid dynamics simulations reveal that the underlying LICVP method improves the incremental property remarkably without sacrifices on other objectives, i.e. the inter-processor communication is optimized simultaneously, and the repartitioning procedure is highly efficient., Comment: 31 pages, 12 figures

Published
2018
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3. A Split Random Time Stepping Method for Stiff and Non-stiff Chemically Reacting Flows

Author

Wang, Jian-Hang, Pan, Shucheng, Hu, Xiangyu Y., and Adams, Nikolaus A.

Subjects
Physics - Computational Physics, Physics - Chemical Physics
Abstract

In this paper, a new fractional step method is proposed for simulating stiff and nonstiff chemically reacting flows. In stiff cases, a well-known spurious numerical phenomenon, i.e. the incorrect propagation speed of discontinuities, may be produced by general fractional step methods due to the under-resolved discretization in both space and time. The previous random projection method has been successfully applied for stiff detonation capturing in under-resolved conditions. Not to randomly project the intermediate state into two presumed equilibrium states (completely burnt or unburnt) as in the random projection method, the present study is to randomly choose the time-dependent advance or stop of a reaction process. Each one-way reaction has been decoupled from the multi-reaction kinetics using operator splitting and the local smeared temperature due to numerical dissipation of shock-capturing schemes is compared with a random one within two limited temperatures corresponding to the advance and its inverse states, respectively, to control the random reaction. The random activation or deactivation in the reaction step is thus promising to correct the deterministic accumulative error of the propagation of discontinuities. Extensive numerical experiments, including model problems and realistic reacting flows in one and two dimensions, demonstrate this expectation as well as the effectiveness and robustness of the method. Meanwhile, for nonstiff problems when spatial and temporal resolutions are fine, the proposed random method recovers the results as general fractional step methods, owing to the increasing possibility of activation with diminishing randomness by adding a shift term., Comment: 48 pages, 14 figures

Published
2018
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4. An incremental-stencil WENO reconstruction for simulation of compressible two-phase flows

Author

Wang, Bing, Xiang, Gaoming, and Hu, Xiangyu Y.

Subjects
Physics - Computational Physics
Abstract

An incremental-stencil WENO reconstruction method, which uses low-order candidate stencils with incrementally increasing width, is proposed for finite-volume simulation of compressible two-phase flow with the quasi-conservative interface model. While recovering the original 5th-order WENO reconstruction in smooth region of the solution, due to the presence of 2-point candidate stencils, the present method is able to handle closely located discontinuities, which is a typical scenario of shock-interface interaction. Furthermore, a MOOD-type positivity preserving approach is applied to ensure physical meaningful reconstruction. Compared with the hybrid method which switches between with the 5th-order WENO and 2nd-order reconstructions, the present method is free of problem-dependent tunable parameters. A number of numerical examples show that the present method achieves small numerical dissipation and good robustness for simulating two-phase flow problems with strong shock-interface interaction and large density ratio., Comment: 46 pages, 19 figures

Published
2017
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25. Implicit large eddy simulations with a high-order TENO scheme

Author

Fu, Lin, Hu, Xiangyu Y., Adams, Nikolaus A., Fu, Lin, Hu, Xiangyu Y., and Adams, Nikolaus A.

Abstract

Although TENO schemes, proposed by Fu et al. (2016), show promising results for turbulence reproduction, they are unsuitable to function as a reliable subgrid LES model by generating excessive dissipation. Meanwhile, the state-ofthe-art implicit LES models, e.g. the localized artificial diffusivity scheme by Kawai et al. (2010), typically depend on shock sensors, which are case-dependent and fail to retain the monotonicity near discontinuities. The difficulty locates on scale-separating the low-wavenumber smooth regions, highwavenumber fluctuations and discontinuities sufficiently and incorporating adequate dissipation into numerical schemes correspondingly. In this paper, we propose a new 8-point 6thorder TENO8-A scheme, which is motivated for gas dynamics and physics-consistent for incompressible and compressible turbulence modeling. While the low-wavenumber smooth region is handled by the optimized linear scheme, with the measurement of local flow scales, the high-wavenumber fluctuations and discontinuities are predicted with adaptive nonlinear dissipation. The new scheme is Galilean invariant and free from physics-based sensors rendering its high generality. Benchmark simulations demonstrate that, while the TENO8-A scheme exhibits exceptional performance in gas dynamics, it faithfully reproduces the kinetic energy evolution for incompressible turbulence and predicts the vorticity, entropy and acoustic modes as good as the physics-motivated ILES models for compressible turbulence decay.

Published
2017

28. Improved Five- and Six-Point Targeted Essentially Nonoscillatory Schemes with Adaptive Dissipation.

Author

Lin Fu, Hu, Xiangyu Y., and Adams, Nikolaus A.

Abstract

This Paper proposes an improvement of the five- and six-point targeted essentially nonoscillatory (TENO5 and TENO6) schemes by introducing an adaptive dissipation-control strategy. Nonlinear numerical dissipation is controlled by dynamically adjusting the cutoff parameter in the TENO weighting strategy according to the first-order smoothness measure of the local flow scales. For the five-point reconstruction, the dissipation bandwidth of the underlying linear scheme is delayed by introducing slight antidissipation at low wave numbers with small dispersion errors. A new sixth-order scale-separation parameter τ5 is derived, and the modified TENO5-A scheme is third-order accurate. For the six-point reconstruction, the dispersion and dissipation errors are optimized separately, resulting in a modified fourth-order TENO6-A scheme. All necessary parameters are determined by spectral analyses and are shown to be problem independent by numerical experiments. A set of benchmark cases, including highly compressible gas dynamics and nearly incompressible and compressible turbulence decay, is considered. Numerical experiments demonstrate that both the proposed TENO5-A and TENO6-A schemes show excellent performance for shocks and broadband turbulence. The turbulence statistics obtained with TENO6-A at coarse resolution are comparable to those from the state-of-the-art implicit large-eddy simulation model and agree well with direct numerical simulation data. [ABSTRACT FROM AUTHOR]

Published
2019
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30. A family of high order targeted ENO scheme for compressible fluid simulations

Author

Fu, Lin, Hu, Xiangyu Y., Adams, Nikolaus A., Fu, Lin, Hu, Xiangyu Y., and Adams, Nikolaus A.

Abstract

Though classical WENO schemes achieve great success and are widely accepted, they show several shortcomings, such as too dissipative for reproducing turbulence and lack of numerical robustness with very high-order, in practical complex simulations. In this paper, we propose a family of high-order targeted ENO schemes for highly compressible fluid simulations involving wide range of sales. In order to increase the robustness of the very high-order classical WENO schemes, the reconstruction is built up by dynamically assembling a set of low-order upwind biased candidate stencils with incrementally increasing widths. Strong scale-separation formulations are proposed to extract the discontinuities from high wave-number physical fluctuations effectively. Coupled with a sharp cut-off technique, one candidate stencil is abandoned only on the condition that it is crossed by strong discontinuities, otherwise always applied with optimal standard weight. The background linear scheme is optimized with the constrain of preserving the approximate dispersion-dissipation condition. While such optimization leads to one-order degeneration, it provides favorable spectral property for intermediate and high wave-number region. By means of quasi-linear analyses and practical numerical experiments, a set of generally case-independent parameters are determined. The formulations of arbitrary high-order schemes are presented in a straightforward way. Five-point and six-point stencil schemes are further designed and analyzed in detail-s. A variety of benchmark-test problems, including broadband waves, strong shock and contact discontinuities are studied. Compared to well established classical WENO schemes, present schemes suggest much improved property of robustness, low numerical dissipation in transition region and sharp discontinuity-capturing capacity, therefore are promising for DNS and LES of shock-turbulence interactions.

Published
2015

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