Improving finite-volume diffusive fluxes through better reconstruction

•A novel reconstruction method and flux discretization scheme is proposed.•Balancing accuracy of third-order least-squares schemes with speed of second-order.•Improvements in accuracy of diffusive flux, flux integral and the solution. The overarching goal of CFD is to compute solutions with low nume...

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Bibliographic Details
Published in:Computers & fluids 2016-11, Vol.139, p.216-232
Main Authors: Sejekan, Chandan B., Ollivier-Gooch, Carl F.
Format: Article
Language:English
Subjects:
Accuracy
Advection
Channel flow
Computational fluid dynamics
Containment
Diffusive flux
Discretization
Errors
Finite volume methods
Fluid flow
Fluxes
High-order methods
Interpolation
Least squares method
Least-squares reconstruction
Navier-Stokes equations
Reconstruction
Stokes law (fluid mechanics)
Unstructured mesh
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Summary:•A novel reconstruction method and flux discretization scheme is proposed.•Balancing accuracy of third-order least-squares schemes with speed of second-order.•Improvements in accuracy of diffusive flux, flux integral and the solution. The overarching goal of CFD is to compute solutions with low numerical error. For finite-volume schemes, this error originates as error in the flux integral. For diffusion problems on unstructured meshes, the diffusive flux (computed from reconstructed gradients) is one order less accurate than the reconstructed solution. Worse, the gradient errors are not smooth, and so no error cancellation accompanies the flux integration, reducing the flux integral to zero order for the second-order schemes. Our aim is to compute the gradient and flux more accurately at the cell boundaries and hence obtain a better flux integral for a slight increase in computational cost. We propose a novel reconstruction method and flux discretization to improve diffusive flux accuracy on cell-centered, isotropic unstructured meshes. Our approach uses a modified least-squares system to reconstruct the solution to second-order accuracy in the H1 norm instead of the prevalent L2 norm, thus ensuring second-order accurate gradients. Either circumcenters or containment centers are chosen as the control-volume reference points based on a criteria to facilitate calculation of second-order gradients at flux quadrature points using a linear interpolation scheme along with a high-accuracy jump term to enhance stability of the system. Numerical results show a significant improvement in the order of accuracy of the computed diffusive flux as well as the flux integral. When applied to a channel flow advection-diffusion problem, the scheme resulted in an increased order of accuracy for the flux integral along with gains in solution accuracy by a factor of two. Similar gains in solution accuracy are also seen when applied to an incompressible Navier-Stokes problem.
ISSN:0045-7930
1879-0747
DOI:10.1016/j.compfluid.2016.08.002