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First the momentum equations are rewritten as
{{Equation| <math> \frac{\partial ( h U_i ) }{\partial t}  
{{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}
- \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_i}
+ \frac{\tau_i }{\rho}
  </math>|2=2}}
  </math>|2=2}}


 
where <math> S_i includes all other terms </math>. The equation is then integrated over the a control volume
The discretized momentum equations are
<math> \frac{\partial  }{\partial t} \int_A h U_i dA  
<math> \frac{\partial  }{\partial t} \int_A h U_i dA  
+ \oint_A \frac{\partial (h U_i U_j )}{\partial x_j} dS
+ \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
- \frac{h}{\rho_0} \frac{\partial p_a }{\partial x_i}
= - g h \oint_F \frac{\partial \eta }{\partial x_i} dF + \int_A S_i dA
+ \frac{\partial }{\partial x_j} \biggl ( \nu_t h \frac{\partial U_i }{\partial x_j} \biggr )
</math>
- \epsilon_{ij3} f_c U_j h = - g h \frac{\partial \eta }{\partial x_i}
+ \frac{\tau_i }{\rho}
</math>





Revision as of 00:16, 30 January 2011

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First the momentum equations are rewritten as

  (2)

where . The equation is then integrated over the a control volume


The continuity equation is discretized as


where the subscript indicates the cell face, with being the water surface elevation, is equal to the dot product of the velocity unit vector and the cell face unit vector.

The coefficient is equal to

The continuity equation is discretized as

where is the dot product of the cell face unit vector and


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

  (1)

for