Circular Basin: Difference between revisions

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Latest revision as of 20:07, 18 April 2013

UNDER CONSTRUCTION

Problem

Dupont (2001) presented an analytical solution for a closed circular domain on an f-plane with a linear bottom friction. The governing equations are

{\frac {\partial HU}{\partial x}}+{\frac {\partial HV}{\partial y}}=0

(1)

-f_{c}V+g{\frac {\partial \eta }{\partial x}}=\kappa U+{\frac {Wy}{RH}}

(2)

f_{c}U+g{\frac {\partial \eta }{\partial y}}=\kappa V

(3)

where $U$ and $V$ are the depth-averaged current velocities in the $x$ and $y$ directions respectively, $g$ is the gravitational constant, $\eta$ is the water surface elevation with respect to mean sea level, $\kappa$ is a linear bottom friction coefficient, $R$ is the radius of the domain, $H$ is the water depth, and $W$ is a constant equal to the gradient of the wind forcing.

Solution

The analytical solution for water surface elevation solution is given by

\eta ={\begin{cases}{\frac {W{{r}^{2}}\sin 2\theta }{4gHR}},&{\mbox{if }}f_{c}=0\\{\frac {W{{f}_{c}}}{RgH\kappa }}\left[{\frac {{R}^{2}}{8}}+{\frac {{r}^{2}}{4}}\left({\frac {\kappa }{{f}_{c}}}\sin 2\theta -1\right)\right],&{\mbox{if }}f_{c}\neq 0\\\end{cases}}

(4)

The current velocities are independent of the Coriolis parameter and are given by

U={\frac {Wy}{2RH\kappa }}

(5)

V=-{\frac {Wx}{2RH\kappa }}

(6)

Setup

Figure 1. Computational grid.

The model is run to steady state from zero current and water level initial conditions with $W=10^{-}4{\text{m}}^{2}{\text{s}}^{-2}$ , $\kappa =10^{-3}{\text{s}}^{-1}$ , and $f_{c}=0$ . Table 1 shows the general settings used for CMS-Flow. Figure 1 shows the computational grid with 5 levels of refinement from 2000 m to 125 m.

Table 1. General Settings for Wind-driven flow in a circular basin

Parameter	Value
Time step	3600 s
Simulation Duration	72 hrs
Ramp Period	24 hrs
Initial Water Depth	100 m
Mixing Terms	Off
Wall Friction	Off
Linear Bottom Friction Coefficient	0.001

Results

No Coriolis

Figure 1. Analytical current velocities and water levels for the case without Coriolis.

Figure 2. Calculated current velocities and water levels for the case without Coriolis.

Table 2. Goodness of fit statistics for the current velocity and water level.

Variable	NRMSE, %	NMAE, %	R^2	Bias
U-Velocity	2.52	0.37	0.999	-8.5e-8 m/s
V-Velocity	2.53	0.38	0.999	7.26e-8 m/s
Water Level	0.03	0.02	0.999	-3.5e-7 m

For a definition of the goodness of fit statistics see Goodness of fit statistics.

With Coriolis

Figure 3. Analytical current velocities and water levels for the case with Coriolis.

Figure 4. Calculated current velocities and water levels for the case with Coriolis.

Table 3. Goodness of fit statistics for the current velocity and water level.

Variable	RRMSE, %	RMAE, %	R^2	Bias
U-Velocity	2.53	0.37	0.999	-8.5e-8 m/s
V-Velocity	2.56	0.37	0.999	6.5e-8 m/s
Water Level	0.03	0.02	0.999	-3.0e-7 m

References

Dupont, F., 2001. Comparison of numerical methods for modelling ocean circulation in basins with irregular coasts. Ph.D. thesis, McGill University, Montreal.

Test Cases

Documentation Portal

Retrieved from "https://cirpwiki.info/index.php?title=Circular_Basin&oldid=9748"

@@ Line 3: / Line 3: @@
 =Problem=
 Dupont (2001) presented an analytical solution for a closed circular domain on an f-plane with a linear bottom friction. The governing equations are
-  {{Equation| <math> -f_c V + g \frac{\partial \eta}{\partial x} =  \kappa U + \frac{W y}{R h} </math>|2=1}}
+{{Equation|<math>
-  {{Equation| <math> f_c U + g \frac{\partial \eta}{\partial y} =  \kappa V </math>|2=2}}
+  \frac{\partial H U}{\partial x} + \frac{\partial H V}{\partial y} = 0
+</math>|1}}
-where <math>U</math> and <math>V</math> are the depth-averaged current velocities in the <math>x</math> and <math>y</math> directions respectively, <math>g<math> is the gravitational constant, <math>\eta</math> is the water surface elevation with respect to mean sea level, <math>\kappa</math> is a linear bottom friction coefficient, <math>R</math> is the radius of the domain, <math>h</math> is the total water depth, and <math>W</math> is a constant equal to the gradient of the wind forcing.
+{{Equation|<math>
+ -f_c V + g \frac{\partial \eta}{\partial x} =  \kappa U + \frac{W y}{R H}
+</math>|2}}
+{{Equation|<math>
+ f_c U + g \frac{\partial \eta}{\partial y} =  \kappa V
+</math>|3}}
+where <math>U</math> and <math>V</math> are the depth-averaged current velocities in the <math>x</math> and <math>y</math> directions respectively, <math>g</math> is the gravitational constant, <math>\eta</math> is the water surface elevation with respect to mean sea level, <math>\kappa</math> is a linear bottom friction coefficient, <math>R</math> is the radius of the domain, <math>H</math> is the water depth, and <math>W</math> is a constant equal to the gradient of the wind forcing.
 =Solution=
 The analytical solution for water surface elevation solution is given by
-{{Equation| <math> \eta =
+{{Equation|<math>
-\begin{cases}
+ \eta =
-\frac{W{{r}^{2}}\sin 2\theta }{4gHR}, & \mbox{if } f_c=0  \\
+  \begin{cases}
-\frac{W{{f}_{c}}}{RgH\kappa }\left[ \frac{{{R}^{2}}}{8}+\frac{{{r}^{2}}}{4}\left( \frac{\kappa }{{{f}_{c}}}\sin 2\theta -1 \right) \right], & \mbox{if } f_c \ne0 \\
+  \frac{W{{r}^{2}}\sin 2\theta }{4gHR}, & \mbox{if } f_c=0  \\
-\end{cases}  </math> |2=1}}
+  \frac{W{{f}_{c}}}{RgH\kappa }\left[ \frac{{{R}^{2}}}{8}+\frac{{{r}^{2}}}{4}\left( \frac{\kappa }{{{f}_{c}}}\sin 2\theta -1 \right) \right], & \mbox{if } f_c \ne0 \\
+  \end{cases}
+</math>|4}}
 The current velocities are independent of the Coriolis parameter and are given by
-{{Equation| <math> U = \frac{W y }{2 R H \kappa} </math> |2=3}}
+{{Equation|<math>
-{{Equation| <math> V = -\frac{W x }{2 R H \kappa} </math> |2=4}}
+ U = \frac{W y }{2 R H \kappa}
+</math>|5}}
+{{Equation|<math>
+ V = -\frac{W x }{2 R H \kappa}
+</math>|6}}
 = Setup =
@@ Line 24: / Line 40: @@
 The model is run to steady state from zero current and water level initial conditions with <math> W = 10^-4 \text{m}^2 \text{s}^{-2} </math>, <math> \kappa = 10^{-3} \text{s}^{-1} </math> , and <math> f_c = 0</math>. Table 1 shows the general settings used for CMS-Flow. Figure 1 shows the computational grid with 5 levels of refinement from 2000 m to 125 m.
+<br style="clear:both" />
 '''Table 1. General Settings for Wind-driven flow in a circular basin'''
 {|border="1"
@@ Line 35: / Line 51: @@
 |Ramp Period || 24 hrs
 |-
-|Initial Water Depth || 10 m
+|Initial Water Depth || 100 m
 |-
 |Mixing Terms || Off
@@ Line 46: / Line 62: @@
 <br style="clear:both" />
+= Results =
+== No Coriolis ==
+[[Image:CB3_Analytical_No_Coriolis_V4.png|thumb|left|600px| Figure 1. Analytical current velocities and water levels for the case without Coriolis.]]
+[[Image:CB3_Calculated_No_Coriolis_V5.png|thumb|right|600px| Figure 2. Calculated current velocities and water levels for the case without Coriolis.]]
-= Results =
+<br style="clear:both" />
-[[Image:CB3_Analytical_No_Coriolis_small_V2.png|thumb|left|600px| Figure 1. Analytical current velocities and water levels.]][[Image:CB3_Calculated_Vel_Eta_small.png|thumb|right|600px| Figure 1. Calculated current velocities and water levels.]]
+'''Table 2. Goodness of fit statistics for the current velocity and water level.'''
+{|border="1"
+|'''Variable''' ||'''NRMSE, %'''||'''NMAE, %'''||'''R^2'''||'''Bias'''
+|-
+|U-Velocity || 2.52 || 0.37 || 0.999 || -8.5e-8 m/s
+|-
+|V-Velocity || 2.53 || 0.38 || 0.999 || 7.26e-8 m/s
+|-
+|Water Level|| 0.03 || 0.02 || 0.999 || -3.5e-7 m
+|}
+* For a definition of the goodness of fit statistics see [[Statistics |  Goodness of fit statistics]].
 <br style="clear:both" />
-Table 2. Goodness of fit statistics for the current velocity and water level
+== With Coriolis ==
+[[Image:CB3_Analytical_Coriolis_V4.png|thumb|left|600px| Figure 3.  Analytical current velocities and water  levels for the case with Coriolis.]]
+[[Image:CB3_Calculated_Coriolis_V5.png|thumb|right|600px| Figure 4. Calculated current velocities and water levels for the case with Coriolis.]]
+<br style="clear:both" />
+'''Table 3. Goodness of fit statistics for the current velocity and water level.'''
 {|border="1"
 |'''Variable''' ||'''RRMSE, %'''||'''RMAE, %'''||'''R^2'''||'''Bias'''
 |-
-|U-Velocity || 3.88 || 0.64 || 0.997 || -4.06e-5
+|U-Velocity || 2.53 || 0.37 || 0.999 || -8.5e-8 m/s
 |-
-|V-Velocity || 3.87 || 0.64 || 0.997 || 4.06e-5
+|V-Velocity || 2.56 || 0.37 || 0.999 || 6.5e-8 m/s
 |-
-|Water Level|| 0.16 || 0.13 || 1.000 || -3.56e-6
+|Water Level|| 0.03 || 0.02 || 0.999 || -3.0e-7 m
 |}
+<br style="clear:both" />
 = References =