Idealized jettied inlet: Difference between revisions

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= Purpose =
= Purpose =


The purpose of this validation case was to evaluate the CMS for
The purpose of this validation case was to evaluate the CMS for wave-induced hydrodynamics in the vicinity of an inlet with two
wave-induced hydrodynamics in the vicinity of an inlet with two
absorbing jetties. The specific model features to be tested are the inline flow and wave coupling, wave-adjusted lateral boundary
absorbing jetties. The specific model features to be tested are the
conditions, and Stokes velocities in the continuity and momentum equations.
inline flow and wave coupling, wave-adjusted lateral boundary
conditions, and Stokes velocities in the continuity and momentum
equations.


= Physical Experiment =
= Physical Experiment =
 
In 2005 the USACE conducted a physical model study to collect both current and wave measurements in the vicinity of an idealized dual
In 2005 the USACE conducted a physical model study to collect both
jetty inlet (Seabergh et al. 2005). The idealized inlet experiment was in a 46-m wide by 99-m long concrete basin with 0.6-m high
current and wave measurements in the vicinity of an idealized dual
walls. Figure 24 shows a map of the facility and basin area. A 1:50 undistorted Froude model scale was used to represent the dimensions of a medium-sized U.S. Atlantic coast inlet. The ocean side parallel contours correspond to an equilibrium profile <math>h=Ax^{2/3}</math>, where h is the still water depth, <math>x</math> is the cross-shore coordinate from the shoreline and <math>A</math>  is a grain size dependant empirical coefficient (equal to 0.1615 m<math>^{1/3}</math> here). For further details on the physical model and previous modeling results with CMS the reader is referred to Seabergh et al. (2005) and Lin et al. (2008). Fully reflective and absorbing jetties were constructed for inlet geometries studied in the physical model. However, all of the tests shown here are for the absorbing jetties since they represent those typically found in coastal applications. The incident wave conditions for the test cases used here are shown in Table 27. The three cases were chosen to cover a wide range of wave heights.
jetty inlet (Seabergh et al. 2005). The idealized inlet experiment was
in a 46-m wide by 99-m long concrete basin with 0.6-m high
walls. Figure 24 shows a map of the facility and basin area. A 1:50
undistorted Froude model scale was used to represent the dimensions of
a medium-sized U.S. Atlantic coast inlet. The ocean side parallel
contours correspond to an equilibrium profile <math>h=Ax^{2/3}</math>, where h is
the still water depth, <math>x</math> is the cross-shore coordinate from the
shoreline and <math>A</math>  is a grain size dependant empirical coefficient (equal
to 0.1615 m<math>^{1/3}</math> here). For further details on the physical model and
previous modeling results with CMS the reader is referred to Seabergh
et al. (2005) and Lin et al. (2008). Fully reflective and absorbing
jetties were constructed for inlet geometries studied in the physical
model. However, all of the tests shown here are for the absorbing
jetties since they represent those typically found in coastal
applications. The incident wave conditions for the test cases used
here are shown in Table 27. The three cases were chosen to cover a
wide range of wave heights.


[[File:Idealized_Inlet_Model_Setup.png |thumb|right|400px|Figure 1. Physical model setup for the idealized inlet case (from Seabergh et al. (2005).]]
[[File:Idealized_Inlet_Model_Setup.png |thumb|right|400px|Figure 1. Physical model setup for the idealized inlet case (from Seabergh et al. (2005).]]
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*Measured at the first offshore station approximately 50 m (prototype) from the jetty tips (see Figure 26).
*Measured at the first offshore station approximately 50 m (prototype) from the jetty tips (see Figure 26).
**Clockwise from shore normal.
**Clockwise from shore normal.
<br  style="clear:both" />


= Model Setup =
= Model Setup =
 
The computational grid and bathymetry for both CMS-Flow and CMS-Wave is shown in Figure 26. The grid has 31,422 active cells and a constant resolution of 10 m (prototype scale). A list of the basic model setup parameters is given in Table 28. A constant zero water level boundary condition was assigned to the offshore boundary of CMS-Flow. A wall boundary condition was used at all boundaries inside the bay.
The computational grid and bathymetry for both
CMS-Flow and CMS-Wave is shown in Figure 26. The grid has 31,422
active cells and a constant resolution of 10 m (prototype scale). A
list of the basic model setup parameters is given in Table 28. A
constant zero water level boundary condition was assigned to the
offshore boundary of CMS-Flow. A wall boundary condition was used at
all boundaries inside the bay.
 


[[File:Idealized_Inlet_Computational_Grid.png |thumb|right|400px|Figure 26. CMS computational grid showing the model bathymetry. Black
[[File:Idealized_Inlet_Computational_Grid.png |thumb|right|400px|Figure 26. CMS computational grid showing the model bathymetry. Black
Line 88: Line 62:




Default CMS settings were used where possible with the Manning’s
Default CMS settings were used where possible with the Manning’s coefficient being the only calibrated parameter (<math>n</math> = 0.025 s/m<math>^{1/3}</math>) for this case study. The roller dissipation coefficient <math>\beta_D</math>  was set to the recommended value for regular waves (<math>\beta_D</math>= 0.05). Both parameters were held constant for all test cases. Including the roller is very
coefficient being the only calibrated parameter (<math>n</math> = 0.025 s/m<math>^{1/3}</math>) for
important for regular waves because it improves the prediction of the long-shore current. The wave- and depth-averaged hydrodynamics
this case study. The roller dissipation coefficient <math>\beta_D</math>  was set to the
equations are solved for depth-uniform currents according to Phillips (1977) and Svendson (2006). The formulation includes Stokes velocities in both the continuity and momentum equations and provides a better prediction of cross-shore currents.
recommended value for regular waves (<math>\beta_D</math>= 0.05). Both parameters were
held constant for all test cases. Including the roller is very
important for regular waves because it improves the prediction of the
long-shore current. The wave- and depth-averaged hydrodynamics
equations are solved for depth-uniform currents according to Phillips
(1977) and Svendson (2006). The formulation includes Stokes velocities
in both the continuity and momentum equations and provides a better
prediction of cross-shore currents.


<br  style="clear:both" />
= Results and Discussion =
= Results and Discussion =
The measured and calculated wave heights and wave-induced nearshore
The measured and calculated wave heights and wave-induced nearshore
currents are presented in plan view vector plots and also cross-shore
currents are presented in plan view vector plots and also cross-shore
Line 147: Line 113:
Figure 4. Cross-shore transects of measured and calculated longshore (left) and cross-shore (right) currents for Case 1 (<math>H</math>=1.65 m, <math>T</math>=11 s). For display purposes, current velocities are shifted by the number indicated on the left hand side of each transect.
Figure 4. Cross-shore transects of measured and calculated longshore (left) and cross-shore (right) currents for Case 1 (<math>H</math>=1.65 m, <math>T</math>=11 s). For display purposes, current velocities are shifted by the number indicated on the left hand side of each transect.


<br  style="clear:both" />
{| class="wikitable" border="1"
{| class="wikitable" border="1"
|+ Table 3. Goodness-of-fit statistics* for Case 1 (<math>H</math>=1.65 m, <math>T</math>=11 s)
|+ Table 3. Goodness-of-fit statistics* for Case 1 (<math>H</math>=1.65 m, <math>T</math>=11 s)
Line 160: Line 127:
|}
|}


 
<br  style="clear:both" />
Case 2 (<math>H</math>=2.0 m, <math>T</math>=11 s)
Case 2 (<math>H</math>=2.0 m, <math>T</math>=11 s)
 
The calculated wave height magnitudes and directions of Case 2 agree well with the measurements especially far away from the jetty (see
The calculated wave height magnitudes and directions of Case 2 agree
Figures 30 and 31). The wave height NRMSE, NMAE, and <math>R^2</math> are 12.33%, 8.05 %, and 0.889, respectively (see Table 30). Closer to the jetty, the differences are larger possibly due to reflected wave energy from the jetty. Even though the jetties were made of small stones and absorbed most of the wave energy, a small portion of the wave energy was reflected. CMS-Wave has the capability to simulate reflecting waves. However, for this study it was assumed that the jetty reflectance was negligible. Additional tests will be conducted in the future to test this hypothesis. The breaker is located at approximately the fourth cross-shore measurement station from the shoreline and was well predicted by the model.
well with the measurements especially far away from the jetty (see
Figures 30 and 31). The wave height NRMSE, NMAE, and <math>R^2</math> are 12.33%,
8.05 %, and 0.889, respectively (see Table 30). Closer to the jetty,
the differences are larger possibly due to reflected wave energy from
the jetty. Even though the jetties were made of small stones and
absorbed most of the wave energy, a small portion of the wave energy
was reflected. CMS-Wave has the capability to simulate reflecting
waves. However, for this study it was assumed that the jetty
reflectance was negligible. Additional tests will be conducted in the
future to test this hypothesis. The breaker is located at
approximately the fourth cross-shore measurement station from the
shoreline and was well predicted by the model.


[[File:Idealized_Inlet_Wave_Heights_Case2.png |thumb|right|400px|Figure 5. Measured and calculate wave height (left) and mean current
[[File:Idealized_Inlet_Wave_Heights_Case2.png |thumb|right|400px|Figure 5. Measured and calculate wave height (left) and mean current
Line 220: Line 175:




 
<br  style="clear:both" />
Case 3 (<math>H</math>=3.25 m, <math>T</math>=8 s)
Case 3 (<math>H</math>=3.25 m, <math>T</math>=8 s)


Figure 33 shows plan-view vector plots of the measured and computed
Figure 33 shows plan-view vector plots of the measured and computed wave heights and current velocities for Case 3. Cross-shore profiles
wave heights and current velocities for Case 3. Cross-shore profiles
of measured and computed wave heights and current velocities are plotted in Figures 34 and 35. For this case, the calculated wave
of measured and computed wave heights and current velocities are
heights are slightly overestimated for most of the measurement locations indicating the wave breaker coefficient was slightly
plotted in Figures 34 and 35. For this case, the calculated wave
overestimated for this steep wave condition. It is noted that wave breaker coefficient calculation is intended for irregular waves and
heights are slightly overestimated for most of the measurement
has not been calibrated for regular waves. Wave directions agree well with the measurements with the exception of a few measurement stations where significant differences are observed in the incident wave angles. From the measurements it appears that the location of the breaker is outside of the measurement stations. The calculated longshore current velocities show the smallest NRMSE and NMAE of all
locations indicating the wave breaker coefficient was slightly
three cases with values of 14 and 11%, respectively. The cross-shore velocities conversely, show the largest NRMSE and NMAE values of all
overestimated for this steep wave condition. It is noted that wave
three cases with values of 28 and 20%, respectively (Table 31). Measured and computed current velocities for Case 3 agree
breaker coefficient calculation is intended for irregular waves and
reasonably well. However, the long-shore current speed tends to be overestimated near the breaker.
has not been calibrated for regular waves. Wave directions agree well
with the measurements with the exception of a few measurement stations
where significant differences are observed in the incident wave
angles. From the measurements it appears that the location of the
breaker is outside of the measurement stations. The calculated
longshore current velocities show the smallest NRMSE and NMAE of all
three cases with values of 14 and 11%, respectively. The cross-shore
velocities conversely, show the largest NRMSE and NMAE values of all
three cases with values of 28 and 20%, respectively
(Table 31). Measured and computed current velocities for Case 3 agree
reasonably well. However, the long-shore current speed tends to be
overestimated near the breaker.




Line 248: Line 191:
(right) vectors for Case 3. Background colors indicate the local water
(right) vectors for Case 3. Background colors indicate the local water
depth corresponding the right color bar.]]
depth corresponding the right color bar.]]




Line 264: Line 206:




 
<br  style="clear:both" />
 
{| class="wikitable" border="1"
{| class="wikitable" border="1"
|+ Table 5. Goodness-of-fit statistics* for Case 3 (<math>H</math>=3.25 m, <math>T</math>=8 s)
|+ Table 5. Goodness-of-fit statistics* for Case 3 (<math>H</math>=3.25 m, <math>T</math>=8 s)
Line 279: Line 220:
|}
|}


<br  style="clear:both" />
= Conclusions and Recommendations =
= Conclusions and Recommendations =
Laboratory experiments were used to validate the CMS for cross-shore and longshore currents and waves near an idealized inlet with two
fully-absorbing jetties. Measurements of regular waves and wave-induced currents were compared with CMS simulations at the prototype scale. The CMS was run using mostly default settings, except for the Manning’s coefficient ((<math>n</math> = 0.025 s/m1/3) and roller
dissipation coefficient (<math>\Beta_D</math> = 0.05). Both parameters were held constant for all three cases. The value of the roller dissipation coefficient applied is the recommended value for regular waves. Model performance and behavior varied case by case but in general the calculated wave heights and wave-induced current velocities agreed reasonably well with measurements as indicated by the goodness-of-fit statistics. Calculated nearshore wave heights and currents upstream of a jetty were found to be within approximately 10-15% and 10-30%, respectively, of measurements. CMS-Wave was able to accurately predict the location of the wave breaker. However, tests were conducted in a physical model without tidal currents, winds, and with well known bathymetry and wave conditions which all represent additional potential sources of error in field applications.  These results indicate that once the model is calibrated for a specific site, using mainly the bottom roughness, the model may be applied at the same site for different wave conditions without having to recalibrate the model. Using the wave- and depth-averaged hydrodynamic equations for depth-uniform currents as derived by Svendson (2006) significantly improved the nearshore currents most noticeably by producing an offshore directed flow or undertow. Including the surface roller improved the longshore currents by moving the peak longshore current closer to the shoreline.


Laboratory experiments were used to validate the CMS for cross-shore
<br  style="clear:both" />
and longshore currents and waves near an idealized inlet with two
fully-absorbing jetties. Measurements of regular waves and
wave-induced currents were compared with CMS simulations at the
prototype scale. The CMS was run using mostly default settings, except
for the Manning’s coefficient ((<math>n</math> = 0.025 s/m1/3) and roller
dissipation coefficient (<math>\Beta_D</math> = 0.05). Both parameters were held
constant for all three cases. The value of the roller dissipation
coefficient applied is the recommended value for regular waves. Model
performance and behavior varied case by case but in general the
calculated wave heights and wave-induced current velocities agreed
reasonably well with measurements as indicated by the goodness-of-fit
statistics. Calculated nearshore wave heights and currents upstream of
a jetty were found to be within approximately 10-15% and 10-30%,
respectively, of measurements. CMS-Wave was able to accurately predict
the location of the wave breaker. However, tests were conducted in a
physical model without tidal currents, winds, and with well known
bathymetry and wave conditions which all represent additional
potential sources of error in field applications.  These results
indicate that once the model is calibrated for a specific site, using
mainly the bottom roughness, the model may be applied at the same site
for different wave conditions without having to recalibrate the
model. Using the wave- and depth-averaged hydrodynamic equations for
depth-uniform currents as derived by Svendson (2006) significantly
improved the nearshore currents most noticeably by producing an
offshore directed flow or undertow. Including the surface roller
improved the longshore currents by moving the peak longshore current
closer to the shoreline.
 
= References =
= References =
* Demirbilek, Z., Lin, L., Seabergh, W.C. (2009). “Laboratory and numerical modeling studies of hydrodynamics near jetties,” Coastal Engineering Journal, 51(2), 143-175.
* Demirbilek, Z., Lin, L., Seabergh, W.C. (2009). “Laboratory and numerical modeling studies of hydrodynamics near jetties,” Coastal Engineering Journal, 51(2), 143-175.

Revision as of 14:04, 18 April 2014

Test C2-Ex4: Idealized jettied inlet with equilibrium beach profile and oblique incident regular waves

Purpose

The purpose of this validation case was to evaluate the CMS for wave-induced hydrodynamics in the vicinity of an inlet with two absorbing jetties. The specific model features to be tested are the inline flow and wave coupling, wave-adjusted lateral boundary conditions, and Stokes velocities in the continuity and momentum equations.

Physical Experiment

In 2005 the USACE conducted a physical model study to collect both current and wave measurements in the vicinity of an idealized dual jetty inlet (Seabergh et al. 2005). The idealized inlet experiment was in a 46-m wide by 99-m long concrete basin with 0.6-m high walls. Figure 24 shows a map of the facility and basin area. A 1:50 undistorted Froude model scale was used to represent the dimensions of a medium-sized U.S. Atlantic coast inlet. The ocean side parallel contours correspond to an equilibrium profile , where h is the still water depth, is the cross-shore coordinate from the shoreline and is a grain size dependant empirical coefficient (equal to 0.1615 m here). For further details on the physical model and previous modeling results with CMS the reader is referred to Seabergh et al. (2005) and Lin et al. (2008). Fully reflective and absorbing jetties were constructed for inlet geometries studied in the physical model. However, all of the tests shown here are for the absorbing jetties since they represent those typically found in coastal applications. The incident wave conditions for the test cases used here are shown in Table 27. The three cases were chosen to cover a wide range of wave heights.

Figure 1. Physical model setup for the idealized inlet case (from Seabergh et al. (2005).


Table 1. Wave conditions (prototype scale) of three test cases from Seabergh et al. (2005).
Case Wave height*, m Wave period, s Wave Direction**
1 1.65 11.0 -20º
2 2.0 11.0 -20º
3 3.25 8.0 -20º
  • Measured at the first offshore station approximately 50 m (prototype) from the jetty tips (see Figure 26).
    • Clockwise from shore normal.


Model Setup

The computational grid and bathymetry for both CMS-Flow and CMS-Wave is shown in Figure 26. The grid has 31,422 active cells and a constant resolution of 10 m (prototype scale). A list of the basic model setup parameters is given in Table 28. A constant zero water level boundary condition was assigned to the offshore boundary of CMS-Flow. A wall boundary condition was used at all boundaries inside the bay.

Figure 26. CMS computational grid showing the model bathymetry. Black circles indicate current velocity and wave height measurement stations used in this study.


Table 2. CMS settings for the Seabergh et al. (2005) experiment.
Parameter Value
Flow time step 6 min
Simulation duration 4 hr
Ramp period duration 3 hr
Manning’s n (both flow and wave grids) 0.025 s/m1/3
Steering interval 1 hr
Roller On
Roller dissipation coefficient 0.05 (default for regular waves)
Stokes velocities On
Wave reflection coefficient 0.0


Default CMS settings were used where possible with the Manning’s coefficient being the only calibrated parameter ( = 0.025 s/m) for this case study. The roller dissipation coefficient was set to the recommended value for regular waves (= 0.05). Both parameters were held constant for all test cases. Including the roller is very important for regular waves because it improves the prediction of the long-shore current. The wave- and depth-averaged hydrodynamics equations are solved for depth-uniform currents according to Phillips (1977) and Svendson (2006). The formulation includes Stokes velocities in both the continuity and momentum equations and provides a better prediction of cross-shore currents.


Results and Discussion

The measured and calculated wave heights and wave-induced nearshore currents are presented in plan view vector plots and also cross-shore transects as discussed below. Note that the wave height and cross-shore profiles are offset by a number indicated to left of each transect which are plotted using different colors. Demirbilek et al. (2009) reported similar results for the wave height using a previous version of CMS. The current velocities reported here are significantly improved with respect to Demirbilek et al. (2009) due to the implementation of the surface roller and Stokes velocities.

Case 1 (=1.65 m, =11 s)

The calculated wave height magnitudes and directions agree well with the measurements with a NMAE of 10.62%(see Figures 27 and 28 and Table 29). The wave model tends to over predict wave refraction near the structure and shoreline. The breaker is located at approximately the third cross-shore measurement station from the shoreline and was well predicted by the model (Figure 28). Measured and computed current velocities for Case 1 are compared in Figures 27 and 29. The velocity field is characterized by a narrow longshore current approximately 75-m wide which is deflected seaward by the south jetty. The NRMSE and NMAE values for the longshore current are approximately 24 and 19%, respectively, while for the cross-shore current, they are significantly smaller at 14 and 10%, respectively (see Table 29). Most of the longshore current is located within the first 2 measurement stations from the shoreline. The calculated cross-shore currents agree well with the measurements except near the jetty where it was overestimated.

Figure 2. Measured and calculated wave height (left) and mean current (right) vectors for Case 1. Background colors indicate the local water depth corresponding to the right color bar.


Figure 3. Cross-shore transects of measured and calculated wave heights for Case 1 ( = 1.65 m, = 11 s). For display purposes, wave heights are shifted by the number indicated on the left hand side of each transect.


framework framework Figure 4. Cross-shore transects of measured and calculated longshore (left) and cross-shore (right) currents for Case 1 (=1.65 m, =11 s). For display purposes, current velocities are shifted by the number indicated on the left hand side of each transect.


  • defined in Appendix A
Table 3. Goodness-of-fit statistics* for Case 1 (=1.65 m, =11 s)
Variable NRMSE,% NMAE,% Bias
Longshore current 24.11 18.74 0.836 -0.141 m/s
Cross-shore current 14.27 10.30 0.907 0.017 m/s
Wave Height 13.96 10.62 0.826 0.051 m


Case 2 (=2.0 m, =11 s) The calculated wave height magnitudes and directions of Case 2 agree well with the measurements especially far away from the jetty (see Figures 30 and 31). The wave height NRMSE, NMAE, and are 12.33%, 8.05 %, and 0.889, respectively (see Table 30). Closer to the jetty, the differences are larger possibly due to reflected wave energy from the jetty. Even though the jetties were made of small stones and absorbed most of the wave energy, a small portion of the wave energy was reflected. CMS-Wave has the capability to simulate reflecting waves. However, for this study it was assumed that the jetty reflectance was negligible. Additional tests will be conducted in the future to test this hypothesis. The breaker is located at approximately the fourth cross-shore measurement station from the shoreline and was well predicted by the model.

Figure 5. Measured and calculate wave height (left) and mean current (right) vectors for Case 2. Background colors indicate the local water depth corresponding the right color bar.
Figure 6. Cross-shore transects of measured and calculated wave heights for Case 2 (=2.0 m, =11 s). For display purposes, wave heights are shifted by the number indicated on the left hand side of each transect.


Measured and calculated current velocities for Case 2 along cross-sectional transects, shown in Figure 32, have NRMSE and NMAE values less than 15 and 13%, respectively. Although the breaker zone for Case 2 is wider than in Case 1, most of the long-shore current is still located within the first 3 measurement stations from the shoreline. The calculated cross-shore currents tend to be underestimated near the shoreline and slightly overestimated outside of the breaker for all cross-shore transects except the one adjacent to the jetty.

Cross-Shore Currents Measured Case2.png
Cross-Shore Currents Calculated Case2.png

Figure 7. Cross-shore transects of measured and calculated long-shore (left) and cross-shore (right) currents for Case 2 (=2.0 m, =11 s). For display purposes, current velocities are shifted by the number indicated on the left hand side of each transect.

Table 4. Goodness-of-fit statistics* for Case 2 (=2.0 m, =11s)
Variable NRMSE,% NMAE,% R2 Bias
Longshore current 14.43 12.24 0.797 -0.007 m/s
Cross-shore current 14.69 11.49 0.930 -0.065 m/s
Wave Height 12.33 8.05 0.889 -0.040 m
*defined in Appendix A



Case 3 (=3.25 m, =8 s)

Figure 33 shows plan-view vector plots of the measured and computed wave heights and current velocities for Case 3. Cross-shore profiles of measured and computed wave heights and current velocities are plotted in Figures 34 and 35. For this case, the calculated wave heights are slightly overestimated for most of the measurement locations indicating the wave breaker coefficient was slightly overestimated for this steep wave condition. It is noted that wave breaker coefficient calculation is intended for irregular waves and has not been calibrated for regular waves. Wave directions agree well with the measurements with the exception of a few measurement stations where significant differences are observed in the incident wave angles. From the measurements it appears that the location of the breaker is outside of the measurement stations. The calculated longshore current velocities show the smallest NRMSE and NMAE of all three cases with values of 14 and 11%, respectively. The cross-shore velocities conversely, show the largest NRMSE and NMAE values of all three cases with values of 28 and 20%, respectively (Table 31). Measured and computed current velocities for Case 3 agree reasonably well. However, the long-shore current speed tends to be overestimated near the breaker.


Figure 8. Measured and calculated wave height (left) and mean current (right) vectors for Case 3. Background colors indicate the local water depth corresponding the right color bar.


Figure 9. Cross-shore transects of measured and calculated wave heights for Case 3 (=3.25 m, =8 s). For display purposes, wave heights are shifted by the number indicated on the left hand side of each transect.


framework framework Figure 10. Cross-shore transects of measured and calculated long-shore (left) and cross-shore (right) currents for Case 3 (=3.25 m, =8 s). For display purposes, current velocities are shifted by the number indicated on the left hand side of each transect.



Table 5. Goodness-of-fit statistics* for Case 3 (=3.25 m, =8 s)
Variable NRMSE, % RMAE, % Bias
Longshore current 13.86 10.61 0.886 -0.189 m/s
Cross-shore current 27.75 20.48 0.676 0.158 m/s
Wave Height 9.98 8.68 0.978 0.223 m
*defined in Appendix A


Conclusions and Recommendations

Laboratory experiments were used to validate the CMS for cross-shore and longshore currents and waves near an idealized inlet with two fully-absorbing jetties. Measurements of regular waves and wave-induced currents were compared with CMS simulations at the prototype scale. The CMS was run using mostly default settings, except for the Manning’s coefficient (( = 0.025 s/m1/3) and roller dissipation coefficient ( = 0.05). Both parameters were held constant for all three cases. The value of the roller dissipation coefficient applied is the recommended value for regular waves. Model performance and behavior varied case by case but in general the calculated wave heights and wave-induced current velocities agreed reasonably well with measurements as indicated by the goodness-of-fit statistics. Calculated nearshore wave heights and currents upstream of a jetty were found to be within approximately 10-15% and 10-30%, respectively, of measurements. CMS-Wave was able to accurately predict the location of the wave breaker. However, tests were conducted in a physical model without tidal currents, winds, and with well known bathymetry and wave conditions which all represent additional potential sources of error in field applications. These results indicate that once the model is calibrated for a specific site, using mainly the bottom roughness, the model may be applied at the same site for different wave conditions without having to recalibrate the model. Using the wave- and depth-averaged hydrodynamic equations for depth-uniform currents as derived by Svendson (2006) significantly improved the nearshore currents most noticeably by producing an offshore directed flow or undertow. Including the surface roller improved the longshore currents by moving the peak longshore current closer to the shoreline.


References

  • Demirbilek, Z., Lin, L., Seabergh, W.C. (2009). “Laboratory and numerical modeling studies of hydrodynamics near jetties,” Coastal Engineering Journal, 51(2), 143-175.
  • Lin, L., Z. Demirbilek, H. Mase, and J. Zheng. (2008). “CMS-Wave: A nearshore spectral wave processes model for coastal inlets and navigation projects,” Technical Report ERDC/CHL TR-08-13, U.S. Army Engineer Research and Development Center, Coastal and Hydraulics Laboratory, Vicksburg, MS.
  • Phillips, O.M. (1977) "Dynamics of the upper ocean," Cambridge University Press. 261 p,
  • Seabergh, W. C., Lin, L., Demirbilek, Z. (2005). “Laboratory study of hydrodynamics near absorbing and fully reflecting jetties,” Technical Report ERDC/CHL (in press), Coastal and Hydraulics Laboratory, U.S. Army Engineer Research and Development Center, Vicksburg, MS.
  • Svendsen, I.A. (2006). "Introduction to nearshore hydrodynamics," Advanced Series on Ocean Engineering, 124, World Scientific Publishing, 722 p.



Test_Cases