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$\int_{A} \nabla \cdot (Γ^{ϕ} h \nabla ϕ) d A = \oint_{S} Γ^{ϕ} h (\nabla ϕ \cdot 𝐧) d S = \sum_{f}^{} {\bar{Γ}}_{f}^{ϕ} {\bar{h}}_{f} Δ l_{f} {({\hat{n}}_{i} \nabla_{i} ϕ)}_{f}$

First the momentum equations are rewritten as

\frac{\partial (h U_{i})}{\partial t} + \frac{\partial}{\partial x_{j}} ((h U_{i} U_{j}) - ν_{t} h \frac{\partial U_{i}}{\partial x_{j}}) = - g h \frac{\partial η}{\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} h U_{i} d A + \oint_{F} \frac{\partial}{\partial x_{j}} [(h U_{i} U_{j}) - ν_{t} h \frac{\partial U_{i}}{\partial x_{j}}] d F = - g h \oint_{F} \frac{\partial η}{\partial x_{i}} d F + \int_{A} S_{i} d A

(2)

The resulting di

$U_{i, P}^{n + 1} = \frac{1}{a_{i, P}} (\sum_{k = 1} a_{i, k} U_{i, k}^{n + 1} + S_{i}) - \frac{h_{P}}{a_{i, P}} \sum_{k = 1} n_{i k} Δ s_{k} p_{k}^{n + 1}$

The continuity equation is discretized as

$h^{n + 1} - 𝐒$

where the subscript $k$ indicates the cell face, $p = g η$ with $η$ being the water surface elevation, $n_{i k}$ 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 $p_{P}^{n + 1} = p_{P}^{n} - g \frac{Δ t}{Δ A_{P}} \sum_{k = 1} n_{k} F_{k}^{n + 1}$

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 (h U_{j})}{\partial x_{j}} = S

(1)

for $j = 1, 2$

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