Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-27T23:17:02.140Z Has data issue: false hasContentIssue false

A TV-Based Iterative Regularization Method for the Solutions of Thermal Convection Problems

Published online by Cambridge University Press:  03 June 2015

Get access

Abstract

Linear/nonlinear and Stokes based-stabilizations for the filter equations for damping out primitive variable (PV) solutions corrupted by uniformly distributed random noises are numerically studied through the natural convection (NC) as well as the mixed convection (MC) environment. The most recognizable filter-scheme is based on a combination of the negative Laplace equation multiplied with the selection of the spatial scale and a linear function in order to preserve the uniqueness of the filtered solution. A more complicated filter-scheme, based on a Stokes problem which couples a filtered velocity and a filtered (artificial) pressure (or Lagrange multiplier) in order to enforce the incompressibility constraint, is also studied. Linear and Stokes based-filters via nested iterative (NI) filters and the consistent splitting scheme (CSS) are proposed for the NC/MC problems. Inspired by the total-variation (TV) model of image diffusion, well preserved feature flow patterns from the corrupted NC/MC environment are obtained by TV-Stokes based-filters together with the CSS. Our experimental results show that our proposed algorithms are effective and efficient in eliminating the unwanted spurious oscillations and preserving the accuracy of thermal convective fluid flows.

Type
Research Article
Copyright
Copyright © Global Science Press Limited 2013

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1]Bowers, A., Rebholz, L., Takhirov, A. and Trenchea, C., Improved accuracy in regularization models of incompressible flow via adaptive nonlinear filtering, To appear in International Journal for Numerical Methods in Fluids.Google Scholar
[2]Chan, H. N. and Chung, E. T., A staggered discontinuous Galerkin method with local TV regularization for the Burgers equation, Submitted.Google Scholar
[3]Chung, E. T. and Lee, C. S., A staggered discontinuous Galerkin method for the convection-diffusion equation, J. Numer. Math., 20 (2012), 131.Google Scholar
[4]Chung, E. T. and Leung, W. T., A sub-grid structure enhanced discontinuous Galerkin method for multiscale diffusion and convection-diffusion problems, Commun. Comput. Phys., 14 (2013), 370392.Google Scholar
[5]Chung, E. T., Kim, H. H. and Widlund, O., Two-level overlapping Schwarz algorithms for a staggered discontinuous Galerkin method, SIAM J. Numer. Anal., 51 (2013), 4767.Google Scholar
[6]Chung, E. T., Chan, T. F. and Tai, X. C., Electrical impedance tomography using level set representation and total variational regularization, J. Comput. Phys., 205 (2005), 357372.Google Scholar
[7]Geurts, B. J. and Holm, D. D., Leray and LANS-α modeling of turbulent mixing, J. Turbulence, 7 (2006), 133.Google Scholar
[8]Mullen, J. S. and Fischer, P. F., Filtering techniques for complex geometry fluid flows, Commun. Numer. Meth. Eng., 15 (1999), 918.Google Scholar
[9]Dunca, A., Optimal design of fluid flow using subproblems reduced by large eddy simulation, Report, DEP, Argonne National Lab., Argonne, IL, 2002.Google Scholar
[10]Layton, W., Manica, C., Neda, M. and Rebholz, L., Numerical analysis and computational testing of a high accuracy Leray-deconvolution model of turbulence, Numer. Meth. Part. Differential Equations, 24 (2007), 555582.Google Scholar
[11]Layton, W., Rebholz, L. and Trenchea, C., Modular nonlinear filter stabilization of methods for higher Reynolds numbers flow, J. Math. Fluid Mech., to appear.Google Scholar
[12]Connors, J., Convergence analysis and computational testing of the finite element discretization of the Navier-Stokes alpha model, Numer. Meth. Part. Differential Equations, 26 (2010), 13281350.Google Scholar
[13]Ervin, V., Layton, W. and Neda, M., Numerical analysis of filter based stabilization for evolution equations, Submitted.Google Scholar
[14]Ervin, V. J., Layton, W. J. and Neda, M., Numerical analysis of a higher order time relaxation model of fluids, Int. J Numer. Anal. Mod., 4 (2007), 648670.Google Scholar
[15]Ingram, R., Layton, W. and Mays, N., A superconvergence theory for a family of iterated regularization methods, Submitted.Google Scholar
[16]Mao, Y. and Gilles, J., Non rigid geometric distortions correction-application to atmospheric turbulence stabilization, To be appeared in Inverse Problems and Imaging.Google Scholar
[17]Mays, N., Iterated Regularization Methods for Solving Inverse Problems, Ph.D. Thesis, University of Pittsburgh, 2011.Google Scholar
[18]Guermond, J. L. and Shen, J., A new class of truly consistent splitting schemes for incompressible flows, J. Comput. Phys., 192 (2003), 262276.Google Scholar
[19]Wong, J. C. F., Numerical simulation of two-dimensional laminar mixed-convection in a lid-driven cavity using the mixed finite element consistent splitting scheme, Int. J.Numer. Methods Heat Fluid Flows, 17 (2007), 4693.CrossRefGoogle Scholar
[20]Park, H. M. and Chung, O. Y., On the solution of an inverse natural convection problem using various conjugate gradient methods, Int. J.Numer. Meth. Eng., 47 (2000), 821842.Google Scholar
[21]Leray, J., Essai sur le mouvement d’un fluide visqueux emplissant l’espace, Acta Math., 63 (1934), 193248.Google Scholar
[22]Reeuwijk, M. van, Jonker, H. J. J. and Hanjalic, K., Incompressibility of the Leray-alpha model for wall-bounded flows, Phys. Fluids, (2006), 018103.CrossRefGoogle Scholar
[23]Scott, K. A. and Lien, F. S., Application of the NS-α model to a recirculating flow, Flow Turbulence Combust., 84 (2010), 167192CrossRefGoogle Scholar
[24]Cao, C., Holm, D. D. and Titi, E. S., On the Clark-α model of turbulence: global regularity and long-time dynamics, J. Turbulence, 6 (2005), 111.Google Scholar
[25]Graham, J. P., Holm, D., Mininni, P. D. and Pouquet, A., Three regularization models of the Navier-Stokes equations, Phys. Fluids, 20 (2008), 035107.Google Scholar
[26]Kim, T. Y., Neda, M., Rebholz, L. G. and Fried, E., A numerical study of the Navier-Stokes-αβ model, Submitted.Google Scholar
[27]Kim, H. H., Chung, E. T. and Lee, C. S., A BDDC algorithm for a class of staggered discontinuous Galerkin methods, Submitted.Google Scholar
[28]Kim, H. H., Chung, E. T. and Lee, C. S., A staggered discontinuous Galerkin method for the Stokes system, Submitted.Google Scholar
[29]Goldstein, T. and Osher, S., The split Bregman method for L1 regularized problems, SIAM J. Imaing Sci, 2 (2009), 323343.Google Scholar
[30]Hahn, J., Wu, C. and Tai, X., Augmented Lagrangian method for generalized TV-Stokes model, J. Sci. Comput., 50 (2012), 235264.Google Scholar
[31]Xiao, Y. and Yang, J., A fast algorithm for total variation image reconstruction from random projections, Submitted.Google Scholar
[32]Zhong, L., Chung, E. T. and Liu, C., Some efficient techniques for the symmetric discontinuous Galerkin approximation of second order elliptic problems, Submitted.Google Scholar