Dorfman-Steiner Theorem

Template:Single source The upwind differencing scheme is a method used in numerical methods in computational fluid dynamics for convection–diffusion problems. This scheme is specific for Peclet number greater than 2 or less than −2

Description

The upwind differencing scheme by taking into account the direction of the flowTemplate:Dn overcomes that inability of the central differencing scheme. This scheme is developed for strong convective flows with suppressed diffusion effects. Also known as ‘Donor Cell’ Differencing Scheme, the convected value of property ф at the cell face is adopted from the upstream node.

It can be described by Steady convection-diffusion partial Differential Equation^[1][2] –

${\displaystyle {\frac {\partial }{\partial t}}(\rho \phi )+\nabla (\rho \mathbf {u} \phi )\,=\nabla (\Gamma \cdot \operatorname {grad} \phi )+S_{\phi }}$

Continuity equation: ${\displaystyle \left(\rho uA\right)_{e}-\left(\rho uA\right)_{w}=0\,}$^[3][4]

where ${\displaystyle \rho }$ is density, ${\displaystyle \Gamma }$ is diffusion coefficient, ${\displaystyle \mathbf {u} }$ is the velocity vector, ${\displaystyle \phi }$ is the property to be computed and ${\displaystyle S_{\phi }}$ is the source term.

After discretization, applying continuity equation, and taking source term equals to zero we get^[5]

Central difference discretized equation

${\displaystyle F_{e}\phi _{e}-F_{w}\phi _{w}\,=D_{e}(\phi _{E}-\phi _{P})-D_{w}(\phi _{P}-\phi _{W})}$ ${\displaystyle \;}$.^[6] .....(1)

${\displaystyle F_{e}-F_{w}\,=0}$ ${\displaystyle \;}$^[7] .....(2)

Lower case denotes the face and upper case denotes node.

Defining variable F as convection mass flux and variable D as diffusion conductanceTemplate:Dn

${\displaystyle F\,=\rho uA}$${\displaystyle \;}$ and ${\displaystyle \;}$${\displaystyle D\,={\frac {\Gamma A}{\delta x}}}$ ${\displaystyle \;}$

Peclet number (Pe) is a non-dimensional parameter determining the comparative strengths of convection and diffusion

Peclet number:

${\displaystyle Pe\,={\frac {F}{D}}\,={\frac {\rho u}{\Gamma /\delta x}}}$ ${\displaystyle \;}$

For a Peclet number of lower value (|Pe| < 2, diffusion is dominant and for this we use the central difference scheme. For other values of and upwind scheme is used for convection dominating flows with Peclet number (|Pe| > 2).

For positive flow direction

${\displaystyle u_{w}>0}$

${\displaystyle u_{e}>0}$

Corresponding upwind scheme equation:

${\displaystyle F_{e}\phi _{P}-F_{w}\phi _{W}\,=D_{e}(\phi _{E}-\phi _{P})-D_{w}(\phi _{P}-\phi _{W})}$^[8] .....(3)

Due to strong convection and suppressedTemplate:Dn diffusion

${\displaystyle \phi _{e}\,=\phi _{P}}$ ^[9]

${\displaystyle \phi _{w}\,=\phi _{W}}$

Rearranging equation (3) gives

${\displaystyle [(D_{w}+F_{w})+D_{e}+(F_{e}-F_{w})]\phi _{P}\,=(D_{w}+F_{w})\phi _{W}+D_{e}\phi _{E})}$${\displaystyle \;}$

Identifying coefficients,

${\displaystyle a_{P}\,=[(D_{w}+F_{w})+D_{e}+(F_{e}-F_{w})]}$ ${\displaystyle \;}$

${\displaystyle a_{W}\,=(D_{w}+F_{w})}$

${\displaystyle a_{E}\,=D_{E}}$

For negative flow direction

${\displaystyle u_{w}<0}$

${\displaystyle u_{e}<0}$

Corresponding upwind scheme equation:

${\displaystyle F_{e}\phi _{E}-F_{w}\phi _{P}\,=D_{e}(\phi _{E}-\phi _{P})-D_{w}(\phi _{P}-\phi _{W})}$^[10] .....(4)

${\displaystyle \phi _{W}\,=\phi _{w}}$

${\displaystyle \phi _{P}\,=\phi _{e}}$

Rearranging equation(4) gives

${\displaystyle [(D_{e}-F_{e})+D_{w}+(F_{e}-F_{w})]\phi _{P}=D_{w}\phi _{W}+(D_{e}-F_{e})\phi _{E}}$

Identifying coefficients,

${\displaystyle a_{W}\,=D_{w}}$

${\displaystyle a_{E}\,=D_{e}-F_{e}}$

We can generalize coefficients as^[11] –

${\displaystyle a_{W}=D_{w}+\max(F_{w},0)}$

${\displaystyle a_{E}=D_{e}+\max(0,-F_{e})}$

File:Comparison of central differencing scheme with upwind differencing scheme for peclet no. greater greater than 2 "OR" less then -2.jpg

Use

Solution in the central difference scheme fails to convergeTemplate:Dn for peclet no. greater than 2 which upwind scheme overcame giving reasonable result.^[12][13] Therefore the upwind differencing scheme is applicable for Pe > 2 for positive flow and Pe < −2 for negative flow. For other values of Pe, this scheme doesn’t give effective solution.

Assessment

Conservativeness^[14]

The upwind differencing scheme formulation is conservative.

Boundedness^[15]

As the coefficients of the discretised equation are always positive hence satisfying the requirements for boundedness and also the coefficient matrix is diagonally dominant therefore no irregularities occur in the solution.

Transportiveness^[16]

Transportiveness is built into the formulation as the scheme already accounts for the flow direction.

Accuracy

Based on the backward differencing formula, the accuracy is only first order on the basis of the Taylor series truncation error. It gives error when flow is not aligned with grid lines. Distribution of transported properties become marked giving diffusion-like appearance, called as the false diffusion. Refinement of grid serves in overcoming the issue of false diffusion. With decrease in the grid size, false diffusion decrease thus increasing the accuracy.

References

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See also

• Central differencing scheme
• Finite difference
• Upwind scheme