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${\displaystyle \underset{A}{\int }\mathrm{\nabla }\cdot \left({\mathrm{\Gamma }}^{\varphi }h\mathrm{\nabla }\varphi \right)\text{d}A=\underset{S}{{\displaystyle \oint }}{\mathrm{\Gamma }}^{\varphi }h(\mathrm{\nabla }\varphi \cdot \mathbf{𝐧})\text{d}S=\sum _f^{}{\overline{\mathrm{\Gamma }}}_f^{\varphi }{\overline{h}}_f\mathrm{\Delta }{l}_f{\left({\hat{n}}_i{\mathrm{\nabla }}_i\varphi \right)}_f}$

First the momentum equations are rewritten as

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

The resulting di

${\displaystyle U_{i,P}^{n+1}=\frac{1}{a_{i,P}}(\sum _{k=1}{a}_{i,k}{U}_{i,k}^{n+1}+S_i)-\frac{h_P}{a_{i,P}}\sum _{k=1}{n}_{ik}\mathrm{\Delta }{s}_k{p}_k^{n+1}}$

The continuity equation is discretized as

${\displaystyle h^{n+1}-\mathbf{𝐒}}$

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

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

The continuity equation is discretized as ${\displaystyle p_P^{n+1}=p_P^n-g\frac{\mathrm{\Delta }t}{\mathrm{\Delta }{A}_P}\sum _{k=1}{n}_k{F}_k^{n+1}}$

where ${\displaystyle n_k}$ is the dot product of the cell face unit vector and

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

for ${\displaystyle j=1,2}$