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$\int \limits _{A}{\nabla \cdot \left({{\Gamma }^{\phi }}h\nabla \phi \right)}{\text{d}}A=\oint \limits _{S}{{{\Gamma }^{\phi }}h\left(\nabla \phi \cdot \mathbf {n} \right)}{\text{d}}S=\sum \limits _{f}^{}{{\bar {\Gamma }}_{f}^{\phi }{{\bar {h}}_{f}}\Delta {{l}_{f}}{{\left({{\hat {n}}_{i}}{{\nabla }_{i}}\phi \right)}_{f}}}$

First the momentum equations are rewritten as

{\frac {\partial (hU_{i})}{\partial t}}+{\frac {\partial }{\partial x_{j}}}{\biggl (}(hU_{i}U_{j})-\nu _{t}h{\frac {\partial U_{i}}{\partial x_{j}}}{\biggr )}=-gh{\frac {\partial \eta }{\partial x_{i}}}+S_{i}

(1)

where $S_{i}$ includes all other terms. The equation is then integrated over the a control volume as

{\frac {\partial }{\partial t}}\int _{A}hU_{i}dA+\oint _{F}{\frac {\partial }{\partial x_{j}}}{\biggl [}(hU_{i}U_{j})-\nu _{t}h{\frac {\partial U_{i}}{\partial x_{j}}}{\biggr ]}dF=-gh\oint _{F}{\frac {\partial \eta }{\partial x_{i}}}dF+\int _{A}S_{i}dA

(2)

The resulting di

$U_{i,P}^{n+1}={\frac {1}{a_{i,P}}}{\biggl (}\sum _{k=1}a_{i,k}U_{i,k}^{n+1}+S_{i}{\biggr )}-{\frac {h_{P}}{a_{i,P}}}\sum _{k=1}n_{ik}\Delta s_{k}p_{k}^{n+1}$

The continuity equation is discretized as

$h^{n+1}-\mathbf {S}$

where the subscript $k$ indicates the cell face, $p=g\eta$ with $\eta$ being the water surface elevation, $n_{ik}$ is equal to the dot product of the velocity unit vector and the cell face unit vector.

The coefficient $a_{i,P}$ is equal to $a_{i,P}=\sum a_{i,k}+a_{P}^{0}$

The continuity equation is discretized as $p_{P}^{n+1}=p_{P}^{n}-g{\frac {\Delta t}{\Delta A_{P}}}\sum _{k=1}n_{k}F_{k}^{n+1}$

where $n_{k}$ is the dot product of the cell face unit vector and

The depth-averaged 2-D continuity and momentum equations are given by

{\frac {\partial h}{\partial t}}+{\frac {\partial (hU_{j})}{\partial x_{j}}}=S

(1)

for $j=1,2$

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@@ Line 1: / Line 1: @@
 This is a page for setting up pages before loading them.
+<math> \int\limits_{A}{\nabla \cdot \left( {{\Gamma }^{\phi }}h\nabla \phi  \right)}\text{d}A=\oint\limits_{S}{{{\Gamma }^{\phi }}h\left( \nabla \phi \cdot \mathbf{n} \right)}\text{d}S=\sum\limits_{f}^{{}}{\bar{\Gamma }_{f}^{\phi }{{{\bar{h}}}_{f}}\Delta {{l}_{f}}{{\left( {{{\hat{n}}}_{i}}{{\nabla }_{i}}\phi  \right)}_{f}}} </math>
+First the momentum equations are rewritten as
 {{Equation| <math> \frac{\partial ( h U_i ) }{\partial t}
-+ \frac{\partial }{\partial x_j} \biggl( (h U_i U_j )-  \nu_t  h \frac{\partial U_i }{\partial x_j} \biggr) dS
++ \frac{\partial }{\partial x_j} \biggl( (h U_i U_j )-  \nu_t  h \frac{\partial U_i }{\partial x_j} \biggr)
-- \epsilon_{ij3} f_c U_j h
+= - g h \frac{\partial \eta }{\partial x_i} + S_i
-= - g h \frac{\partial \eta }{\partial x_i}
+  </math>|2=1}}
- - \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_i}
- + \frac{\tau_i }{\rho}
-  </math>|2=2}}
+where <math>S_i</math> includes all other terms. The equation is then integrated over the a control volume as
+{{Equation| <math> \frac{\partial  }{\partial t} \int_A h U_i dA
++ \oint_F \frac{\partial }{\partial x_j} \biggl[ (h U_i U_j) -  \nu_t h \frac{\partial U_i }{\partial x_j} \biggr] dF
+ = - g h \oint_F \frac{\partial \eta }{\partial x_i} dF + \int_A S_i dA
+</math>|2=2}}
-The discretized momentum equations are
+The resulting di
-<math> \frac{\partial  }{\partial t} \int_A h U_i dA
-+ \oint_A \frac{\partial (h U_i U_j )}{\partial x_j} dS
-- \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_i}
-+ \frac{\partial }{\partial x_j} \biggl ( \nu_t  h \frac{\partial U_i }{\partial x_j} \biggr )
-- \epsilon_{ij3} f_c U_j h = - g h \frac{\partial \eta }{\partial x_i}
- + \frac{\tau_i }{\rho}
- </math>

Temp: Difference between revisions

Latest revision as of 19:00, 17 March 2011

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