Model help:TopoFlow-Channels-Diffusive Wave: Difference between revisions

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__NOTOC__
__NOTOC__
==<big><big>{{PAGENAME}}</big></big>==
==<big><big>{{PAGENAME}}</big></big>==
The module is used to compute flow routing in a D8-based, spatial hydrologic model.   
The module is used to compute flow routing in a D8-based, spatial hydrologic model with diffusive wave method.   


==Model introduction==
==Model introduction==
This process component is part of a spatially-distributed hydrologic model called TopoFlow, but it can now be used as a stand-alone model. It uses the "diffusive wave" method to compute flow velocities for all of the channels in a D8-based river network. This wave method is similar to the kinematic wave method for modeling flow in open channels, but instead of a simple balance between friction and gravity, this method includes the pressure gradient that is induced by a water-depth gradient in the downstream direction. This means that instead of using bed slope in Manning's equation or the law of the wall, the water-surface slope is used. One consequence of this is that water is able to move across flat areas that have a bed slope of zero. Local and convective accelerations in the momentum equations are still neglected, just as is done in the kinematic wave method. For more information.  
This process component is part of a spatially-distributed hydrologic model called TopoFlow, but it can now be used as a stand-alone model. It uses the "diffusive wave" method to compute flow velocities for all of the channels in a D8-based river network. This wave method is similar to the kinematic wave method for modeling flow in open channels, but instead of a simple balance between friction and gravity, this method includes the pressure gradient that is induced by a water-depth gradient in the downstream direction. This means that instead of using bed slope in Manning's equation or the law of the wall, the water-surface slope is used. One consequence of this is that water is able to move across flat areas that have a bed slope of zero. Local and convective accelerations in the momentum equations are still neglected, just as is done in the kinematic wave method.  




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!Parameter!!Description!!Unit
!Parameter!!Description!!Unit
|-valign="top"
|-valign="top"
|width="20%"|Component status:
|width="20%"| Component status
|width="60%"| Enabled / Disabled
|width="60%"| Enabled / Disabled
|width="20%"| [-]
|width="20%"| [-]
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| Time step
| Time step
|  
|  
| [sec]
|-
| D8 flow code file
| grid of D8 flow codes in binary file
| [-]
| [-]
|-
|-
| D8 flow code file
| D8 slope file
|
| grid of D8 flow slopes in binary file
| [-]
|-
| Manning flag
| Option to use Manning'n for roughness
| [-]
|-
| Law of Wall flag
| Option to use Law of Wall for roughness
| [-]
|-
| Manning N type
| grid of D8 flow slopes in binary file ( Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence)
| [-]
| [-]
|-
| Manning N
| Manning'n value
| [m / s^1/3]
|-
| Roughness z<sub>0</sub> type
| Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence
| [m]
|-
| Roughness z<sub>0</sub>
| Law of Wall roughness value
| [m]
|-
|-
|}
|}
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==Uses ports==
==Uses ports==
<span class="remove_this_tag">This will be something that the CSDMS facility will add</span>
 
• Meteorology <br />
• Snow (Snowmelt) <br />
• Evap (Evaporation) <br />
• Infil (Infiltration) <br />
• Satzone (Subsurface flow in saturated zone) <br />
• Ice (Icemelt) <br />
• Diversions (sources, sinks, canals) <br />


==Provides ports==
==Provides ports==
<span class="remove_this_tag">This will be something that the CSDMS facility will add</span>
 
• Channels (surface water flow in a network of channels) <br />
• Configure (tabbed dialog GUI to change settings) <br />
• Run (only if used as the Driver) <br />


==Main equations==
==Main equations==
* Mass conservation equation
* Mass conservation equation
::::{|
::::{|
|width=500px|<math>\Delta V \left (i,t \right)=\Delta t \left (R \left (i,t \right) \Delta x \Delta y -Q \left (i,t \right) +\Sigma_{k} Q \left (k,t \right) \right) </math>
|width=500px|<math>\Delta V \left (i,t \right)=\Delta t \ast [ R \left (i,t \right) \Delta x \Delta y -Q \left (i,t \right) +\Sigma_{k} Q \left (k,t \right) ] </math>
|width=50px align="right"|(1)
|width=50px align="right"|(1)
|}
|}
* Mean water depth in channel segment (if θ > 0 )
* Mean water depth in channel segment (if θ > 0 )
::::{|
::::{|
|width=500px|<math>d=\left (\left (w^2 + 4 \tan \left (\Theta\right) V / L\right)^{\frac{1}{2}} -w\right) / \left ( 2 \tan \left (\Theta\right)\right) </math>
|width=500px|<math>d=\{ [w^2 + 4 \tan \left (\theta\right) V / L] ^{\frac{1}{2}} -w\} / [ 2 \tan \left (\theta\right)] </math>
|width=50px align="right"|(2)
|width=50px align="right"|(2)
|}
|}
* mean water depth in channel  (if θ = 0)
* mean water depth in channel  (if θ = 0)
::::{|
::::{|
|width=500px|<math>d= V / \left (w L\right) </math>
|width=500px|<math>d= V / [ w \ast L] </math>
|width=50px align="right"|(3)
|width=50px align="right"|(3)
|}
|}
* discharge of water
* discharge of water
::::{|
::::{|
|width=500px|<math>Q=v A_{w} </math>
|width=500px|<math>Q=v \ast A_{w} </math>
|width=50px align="right"|(4)
|width=50px align="right"|(4)
|}
|}
* section-averaged velocity (Manning's formula)
* section-averaged velocity (Manning's formula)
::::{|
::::{|
|width=500px|<math>v=n^{-1} R_{h}^{\frac{2}{3}} S^{\frac{1}{2}} </math>
|width=500px|<math>v=n^{-1} \ast R_{h}^{\frac{2}{3}} \ast S^{\frac{1}{2}} </math>
|width=50px align="right"|(5)
|width=50px align="right"|(5)
|}
|}
* section-averaged velocity (Law of the Wall)
* section-averaged velocity (Law of the Wall)
::::{|
::::{|
|width=500px|<math>v=\left (g R_{h} S\right)^{\frac{1}{2}} LN\left (a d / z_{0}\right) /\Kappa </math>
|width=500px|<math>v=\left (g \ast R_{h} \ast S\right)^{\frac{1}{2}} LN\left (a \ast d / z_{0}\right) /\kappa </math>
|width=50px align="right"|(6)   
|width=50px align="right"|(6)   
|}
|}
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* wetted cross-sectional area of a trapezoid
* wetted cross-sectional area of a trapezoid
::::{|
::::{|
|width=500px|<math>A_{w}= d \left (w + \left (d \tan \left (\Theta\right)\right)\right) </math>
|width=500px|<math>A_{w}= d \ast \left (w + \left (d \ast \tan \left (\theta\right)\right)\right) </math>
|width=50px align="right"|(8)
|width=50px align="right"|(8)
|}
* Wetted perimeter of a trapezoid
::::{|
|width=500px|<math>P_{w}= w + \left ( 2 \ast d / cos\left (\theta\right)\right)</math>
|width=50px align="right"|(9)
|}  
|}  
* wetted volume of a trapezoidal channel
* wetted volume of a trapezoidal channel
::::{|
::::{|
|width=500px|<math>V_{w}=d^2 \left (L \tan \left (\Theta\right)\right) +d \left (L w\right) </math>
|width=500px|<math>V_{w}=d^2 \ast \left (L \ast \tan \left (\theta\right)\right) +d \ast \left (L \ast w\right) </math>
|width=50px align="right"|(9)
|width=50px align="right"|(10)
|}  
|}  


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| ΔV
| ΔV
| change in water volume
| change in water volume
| m^3
| m<sup>3</sup>
|-
|-
| Δt
| Δt
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| V
| V
| water volume
| water volume
| m^3
| m<sup>3</sup>
|-
|-
| L
| L
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| A<sub>w</sub>
| A<sub>w</sub>
| wetted cross-sectional area of a trapezoid
| wetted cross-sectional area of a trapezoid
| m^2
| m<sup>2</sup>
|-
|-
| n
| n
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| m
| m
|-
|-
| V<sub>w</sub>
| wetted volume of a trapezoid channel
| m
|-
| S
| S
| bed slope
| bed slope
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| g
| g
| gravity acceleration
| gravity acceleration
| m / s^2
| m / s<sup>2</sup>
|-
|-
| z<sub>0</sub>
| z<sub>0</sub>
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|-
|-
| κ  
| κ  
| Von Karman's constant
| Von Karman's constant, equals to 0.41
| -
| -
|-   
|-   
| a  
| a  
|  
| constant
| -  
| -  
|-
|-
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| Q
| Q
| discharge of water
| discharge of water
| m^3 / s
| m<sup>3</sup> / s
|-
|-
| v
| v
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   </div>
   </div>
</div>
</div>
==Notes==
==Notes==
* Note on Input Parameters
 
'''''Notes on Input Parameters'''''
 
The input variables for the diffusive wave method should usually be specified as grids, except in special cases.
The input variables for the diffusive wave method should usually be specified as grids, except in special cases.


Single grids and grid sequences are assumed to be stored as RTG and RTS files, respectively. Time series are assumed to be stored as text files, with one value per line. For a time series or grid sequence, the time between values must coincide with the timestep provided.
Single grids and grid sequences are assumed to be stored as RTG and RTS files, respectively. Time series are assumed to be stored as text files, with one value per line. For a time series or grid sequence, the time between values must coincide with the timestep provided.


Flow directions are determined by a grid of D8 flow codes. All grids are assumed to be stored as RTG (RiverTools Grid) files and flow codes are assumed to follow the Jenson (1984) convention (see above) that is also used for RiverTools D8 flow grids. Flow grids and slope grids can be created by RiverTools or a similar program and the other grids can be created using tools in the TopoFlow Create menu.
Flow directions are determined by a grid of D8 flow codes. All grids are assumed to be stored as RTG (RiverTools Grid) files and flow codes are assumed to follow the Jenson (1984) convention (i.e. [NE,E,SE,S,SW,W,NW,N] → [1,2,4,8,16,32,64,128]) that is also used for RiverTools D8 flow grids. Flow grids and slope grids can be created by RiverTools or a similar program and the other grids can be created using tools in the TopoFlow Create menu.


Bed slope, S, can be computed from a DEM by using the Create → Profile-smoothed DEM dialog or by using hydrologic GIS software such as RiverTools.
Bed slope, S, can be computed from a DEM by using the Create → Profile-smoothed DEM dialog or by using hydrologic GIS software such as RiverTools.
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It is physically unrealistic to specify a spatially uniform initial flow depth by entering a scalar value greater than zero for init_depth. This will result in a very large peak in the hydrograph and may cause TopoFlow to crash. The Create → RTG File for Initial Depth tool can be used to create a grid of initial flow depths that varies spatially and is in steady-state equilibrium with a specified baseflow recharge rate.  
It is physically unrealistic to specify a spatially uniform initial flow depth by entering a scalar value greater than zero for init_depth. This will result in a very large peak in the hydrograph and may cause TopoFlow to crash. The Create → RTG File for Initial Depth tool can be used to create a grid of initial flow depths that varies spatially and is in steady-state equilibrium with a specified baseflow recharge rate.  


* Note on Equations
'''''Notes on the Equations'''''
Conservation of mass, in integral form, is represented by the first three equations above. The quantity, R, that appears in the first equation is known as the effective rainrate or excess rainrate and represents the sum of all vertical contributions to a grid cell's mass balance. R is computed as R = (P + M + G) - (I + E), where P = precipitation, M = snowmelt, G = seepage from subsurface, I = infiltration and E = evapotranspiration. (Note that R is technically not the same as the runoff, since runoff includes horizontal fluxes.) The summation sign in the first equation adds up all horizontal inflows to a grid cell from its neighbor grid cells. Mean channel flow depth, d, is then computed from channel geometry and the water volume that is computed for the corresponding grid cell. Note that channel length depends on distance between grid cell centers and sinuosity, while cross-sections are trapezoidal. When the bank angle, θ is greater than zero, the flow depth required to accomodate the water volume is computed by solving the last equation (a quadratic) for d to get the second equation.
 
All variables and their units can be seen by expanding the Nomenclature section above.
 
Conservation of mass, in integral form, is represented by the equations above. The quantity, R, that appears in the first equation is known as the effective rainrate or excess rainrate and represents the sum of all vertical contributions to a grid cell's mass balance. R is computed as R = (P + M + G) - (I + E), where P = precipitation, M = snowmelt, G = seepage from subsurface, I = infiltration and E = evapotranspiration. (Note that R is technically not the same as the runoff, since runoff includes horizontal fluxes.) The summation sign in the first equation adds up all horizontal inflows to a grid cell from its neighbor grid cells. Mean channel flow depth, d, is then computed from channel geometry and the water volume that is computed for the corresponding grid cell. Note that channel length depends on distance between grid cell centers and sinuosity, while cross-sections are trapezoidal. When the bank angle, θ is greater than zero, the flow depth required to accomodate the water volume is computed by solving the last equation (a quadratic) for d to get the second equation.


The diffusive wave method is similar to the kinematic wave method for modeling flow in open channels, but instead of a simple balance between friction and gravity, this method includes the pressure gradient that is induced by a water-depth gradient in the downstream direction. This means that instead of using bed slope in Manning's equation or the law of the wall, the water-surface slope is used. One consequence of this is that water is able to move across flat areas that have a bed slope of zero. Local and convective accelerations in the momentum equations are still neglected, just as is done in the kinematic wave method. For more information, see the help page for the kinematic wave method.  
The diffusive wave method is similar to the kinematic wave method for modeling flow in open channels, but instead of a simple balance between friction and gravity, this method includes the pressure gradient that is induced by a water-depth gradient in the downstream direction. This means that instead of using bed slope in Manning's equation or the law of the wall, the water-surface slope is used. One consequence of this is that water is able to move across flat areas that have a bed slope of zero. Local and convective accelerations in the momentum equations are still neglected, just as is done in the kinematic wave method. For more information, see the help page for the kinematic wave method.  


* Note on the current version
'''''Note on the current version'''''
In the current version of TopoFlow (1.5 beta), water-surface slopes are set to zero if they ever become negative (implying upstream flow).  
 
In the current version of TopoFlow (1.5 beta), water-surface slopes are set to zero if they ever become negative (implying upstream flow).


==Examples==
==Examples==
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<span class="remove_this_tag">Follow the next steps to include images / movies of simulations:</span>
<span class="remove_this_tag">Follow the next steps to include images / movies of simulations:</span>
* <span class="remove_this_tag">Upload file: http://csdms.colorado.edu/wiki/Special:Upload</span>
* <span class="remove_this_tag">Upload file: https://csdms.colorado.edu/wiki/Special:Upload</span>
* <span class="remove_this_tag">Create link to the file on your page: <nowiki>[[Image:<file name>]]</nowiki>.</span>
* <span class="remove_this_tag">Create link to the file on your page: <nowiki>[[Image:<file name>]]</nowiki>.</span>


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==Developer(s)==
==Developer(s)==
[[User:Gparker|Scott Peckham]]
[[User:Peckhams|Scott Peckham]]


==References==
==References==
* Schlicting, H. (1960) Boundary Layer Theory, 4th ed., McGraw-Hill, New York, 647 pp.
* Schlicting, H. (1960) Boundary Layer Theory, 4th ed., McGraw-Hill, New York, 647 pp.
==Links==
==Links==
* [[Model:TopoFlow-Channels-Diffusive Wave]]
 
* [[Model help:TopoFlow-Channels-Kinematic Wave]]
* [[Model help:TopoFlow-Channels-Dynamic Wave]]
* [[Model help:TopoFlow-Diversions]]
 
* [[Model:TopoFlow-Channels-Diffusive Wave]] (Model metadata)
* [[Model:TopoFlow]]
* [[Model:TopoFlow]]


[[Category:Modules]]
[[Category:Modules]]

Latest revision as of 17:18, 19 February 2018

The CSDMS Help System

TopoFlow-Channels-Diffusive Wave

The module is used to compute flow routing in a D8-based, spatial hydrologic model with diffusive wave method.

Model introduction

This process component is part of a spatially-distributed hydrologic model called TopoFlow, but it can now be used as a stand-alone model. It uses the "diffusive wave" method to compute flow velocities for all of the channels in a D8-based river network. This wave method is similar to the kinematic wave method for modeling flow in open channels, but instead of a simple balance between friction and gravity, this method includes the pressure gradient that is induced by a water-depth gradient in the downstream direction. This means that instead of using bed slope in Manning's equation or the law of the wall, the water-surface slope is used. One consequence of this is that water is able to move across flat areas that have a bed slope of zero. Local and convective accelerations in the momentum equations are still neglected, just as is done in the kinematic wave method.


Model parameters

Parameter Description Unit
Component status Enabled / Disabled [-]
Input directory The location of the input files [-]
Output directory The location for the output files [-]
Site prefix [-]
Case prefix [-]
Number of steps Number of simulation steps [-]
Time step [sec]
D8 flow code file grid of D8 flow codes in binary file [-]
D8 slope file grid of D8 flow slopes in binary file [-]
Manning flag Option to use Manning'n for roughness [-]
Law of Wall flag Option to use Law of Wall for roughness [-]
Manning N type grid of D8 flow slopes in binary file ( Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence) [-]
Manning N Manning'n value [m / s^1/3]
Roughness z0 type Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence [m]
Roughness z0 Law of Wall roughness value [m]
Parameter Description Unit
Bed width type Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence [-]
Bank width bed width of trapezoid cross-section [m]
Bank angle type Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence [-]
Bank angle bank angle of trapezoid cross-section [degree]
Init. depth type Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence [-]
Init. depth initiate flow depth (If scalar, use 0.0) [m]
Sinuosity type Allowed input types: Scalar / Grid /Time_Series /Grid_Sequence [-]
Sinuosity absolute channel sinuosity [m / m]
Parameter Description Unit
Save grid timestep time interval between saved grids [sec]
Save Q grids toggle Option to save computed Q grids [-]
Save Q grids file file name for Q grid stack [m^3 / s]
Save u grids toggle Option to save computed u grids [-]
Save u grids file file name for u grid stack [m / s]
Save d grids toggle Option to save computed d grids [-]
Save d grids file file name for d grid stack [m]
Save f grids toggle Option to save computed f grids [-]
Save f grids file file name for f grid stack
Parameter Description Unit
Save pixels timestep time interval between time series vales [sec]
Save Q pixels toggle Option to save computed Q time series [-]
Save Q pixels file file name for Q time series [m^3 / s]
Save u pixels toggle Option to save computed u time series [-]
Save u pixels file file name for u time series [m / s]
Save d pixels toggle Option to save computed d time series [-]
Save d pixels file file name for d time series [m]
Save f pixels toggle Option to save computed f time series [-]
Save f pixels file file name for f time series [-]

Uses ports

• Meteorology
• Snow (Snowmelt)
• Evap (Evaporation)
• Infil (Infiltration)
• Satzone (Subsurface flow in saturated zone)
• Ice (Icemelt)
• Diversions (sources, sinks, canals)

Provides ports

• Channels (surface water flow in a network of channels)
• Configure (tabbed dialog GUI to change settings)
• Run (only if used as the Driver)

Main equations

  • Mass conservation equation
[math]\displaystyle{ \Delta V \left (i,t \right)=\Delta t \ast [ R \left (i,t \right) \Delta x \Delta y -Q \left (i,t \right) +\Sigma_{k} Q \left (k,t \right) ] }[/math] (1)
  • Mean water depth in channel segment (if θ > 0 )
[math]\displaystyle{ d=\{ [w^2 + 4 \tan \left (\theta\right) V / L] ^{\frac{1}{2}} -w\} / [ 2 \tan \left (\theta\right)] }[/math] (2)
  • mean water depth in channel (if θ = 0)
[math]\displaystyle{ d= V / [ w \ast L] }[/math] (3)
  • discharge of water
[math]\displaystyle{ Q=v \ast A_{w} }[/math] (4)
  • section-averaged velocity (Manning's formula)
[math]\displaystyle{ v=n^{-1} \ast R_{h}^{\frac{2}{3}} \ast S^{\frac{1}{2}} }[/math] (5)
  • section-averaged velocity (Law of the Wall)
[math]\displaystyle{ v=\left (g \ast R_{h} \ast S\right)^{\frac{1}{2}} LN\left (a \ast d / z_{0}\right) /\kappa }[/math] (6)
  • hydraulic radius
[math]\displaystyle{ R_{h}= A_{w} /P_{w} }[/math] (7)
  • wetted cross-sectional area of a trapezoid
[math]\displaystyle{ A_{w}= d \ast \left (w + \left (d \ast \tan \left (\theta\right)\right)\right) }[/math] (8)
  • Wetted perimeter of a trapezoid
[math]\displaystyle{ P_{w}= w + \left ( 2 \ast d / cos\left (\theta\right)\right) }[/math] (9)
  • wetted volume of a trapezoidal channel
[math]\displaystyle{ V_{w}=d^2 \ast \left (L \ast \tan \left (\theta\right)\right) +d \ast \left (L \ast w\right) }[/math] (10)

Notes

Notes on Input Parameters

The input variables for the diffusive wave method should usually be specified as grids, except in special cases.

Single grids and grid sequences are assumed to be stored as RTG and RTS files, respectively. Time series are assumed to be stored as text files, with one value per line. For a time series or grid sequence, the time between values must coincide with the timestep provided.

Flow directions are determined by a grid of D8 flow codes. All grids are assumed to be stored as RTG (RiverTools Grid) files and flow codes are assumed to follow the Jenson (1984) convention (i.e. [NE,E,SE,S,SW,W,NW,N] → [1,2,4,8,16,32,64,128]) that is also used for RiverTools D8 flow grids. Flow grids and slope grids can be created by RiverTools or a similar program and the other grids can be created using tools in the TopoFlow Create menu.

Bed slope, S, can be computed from a DEM by using the Create → Profile-smoothed DEM dialog or by using hydrologic GIS software such as RiverTools.

The current version assumes that all channels have trapezoidal cross-sections (see Notes below) but allows bottom-width and bank angle to vary spatially as grids. TopoFlow has pre-processing tools in the Create menu for creating grids of bed width, bank angle and bed roughness. The Create → Channel Geometry Grids → With Area Grid tool allows you to parameterize these variables as power-law functions of contributing area. The Create → Channel Geometry Grids → With HS Order Grid tool allows you to assign values based on Horton-Strahler order.

Each pixel is classified as either a hillslope pixel (overland flow) or a channel pixel (channelized flow) and appropriate parameters must be used for each. For overland flow, w >> d, Rh → d, and bank angle drops out. Overland flow can then be modeled with a large value of Manning's n, such as 0.3. For channelized flow, the variation of n with bed grain size can be modeled with Strickler's equation as explained in the Notes below.

If a sinuosity greater than 1 is specified, then bed slopes are reduced by dividing them by this value. As with the other variables, it is most appropriate to specify a grid in this case.

It is physically unrealistic to specify a spatially uniform initial flow depth by entering a scalar value greater than zero for init_depth. This will result in a very large peak in the hydrograph and may cause TopoFlow to crash. The Create → RTG File for Initial Depth tool can be used to create a grid of initial flow depths that varies spatially and is in steady-state equilibrium with a specified baseflow recharge rate.

Notes on the Equations

All variables and their units can be seen by expanding the Nomenclature section above.

Conservation of mass, in integral form, is represented by the equations above. The quantity, R, that appears in the first equation is known as the effective rainrate or excess rainrate and represents the sum of all vertical contributions to a grid cell's mass balance. R is computed as R = (P + M + G) - (I + E), where P = precipitation, M = snowmelt, G = seepage from subsurface, I = infiltration and E = evapotranspiration. (Note that R is technically not the same as the runoff, since runoff includes horizontal fluxes.) The summation sign in the first equation adds up all horizontal inflows to a grid cell from its neighbor grid cells. Mean channel flow depth, d, is then computed from channel geometry and the water volume that is computed for the corresponding grid cell. Note that channel length depends on distance between grid cell centers and sinuosity, while cross-sections are trapezoidal. When the bank angle, θ is greater than zero, the flow depth required to accomodate the water volume is computed by solving the last equation (a quadratic) for d to get the second equation.

The diffusive wave method is similar to the kinematic wave method for modeling flow in open channels, but instead of a simple balance between friction and gravity, this method includes the pressure gradient that is induced by a water-depth gradient in the downstream direction. This means that instead of using bed slope in Manning's equation or the law of the wall, the water-surface slope is used. One consequence of this is that water is able to move across flat areas that have a bed slope of zero. Local and convective accelerations in the momentum equations are still neglected, just as is done in the kinematic wave method. For more information, see the help page for the kinematic wave method.

Note on the current version

In the current version of TopoFlow (1.5 beta), water-surface slopes are set to zero if they ever become negative (implying upstream flow).

Examples

An example run with input parameters, BLD files, as well as a figure / movie of the output

Follow the next steps to include images / movies of simulations:

See also: Help:Images or Help:Movies

Developer(s)

Scott Peckham

References

  • Schlicting, H. (1960) Boundary Layer Theory, 4th ed., McGraw-Hill, New York, 647 pp.

Links

Retrieved from "https://csdms.colorado.edu/csdms_wiki/index.php?title=Model_help:TopoFlow-Channels-Diffusive_Wave&oldid=216511"