Ground evaporation formula (Water Overlay): Difference between revisions

Revision as of 13:33, 25 February 2021

Underground evaporation is calculated per cell.

For all underground evaporation calculation, the ground water depth at time t is used.

$d_{gw,t}=b_{s}-w_{g,t}$

Feddes oxygen stress factor:

$f_{o}={\begin{cases}1.0&{\text{if }}d_{gw,t}{\text{ is }}\geq d_{r,3}\\{\frac {d_{gw,t}-d_{r,4}}{d_{r,3}-d_{r,4}}}&{\text{if }}d_{gw,t}{\text{ is }}\geq d_{r,4}\\0.0&{\text{otherwise}}\end{cases}}$

Feddes saturated zone root update factor:

$f_{s}={\begin{cases}0.0&{\text{if }}d_{gw,t}{\text{ is }}\geq d_{r,1}\\1.0-{\frac {d_{gw,t}-d_{r,2}}{d_{r,1}-d_{r,2}}}&{\text{if }}d_{gw,t}{\text{ is }}\geq d_{r,2}\\1.0&{\text{otherwise}}\end{cases}}$

Max potential evaporation:

$E_{max}=f_{t}\cdot E_{w,t}\cdot f_{o}$

Evaporation unsaturated:

$E_{u}={\begin{cases}0.0&{\text{if }}d_{gw,t}{\text{ is }}\geq 0.0\\min(E_{max},h_{u}\cdot {\frac {d_{r,1}}{d_{gw,t}}})&{\text{otherwise}}\\\end{cases}}$

Potential evaporation saturated:

$d_{s}=w_{g,t}-(b_{s}-d_{gb})$

$d_{r}=max(0.0,w_{g,t}-(b_{s}-d_{r,1}))$

$E_{p,s}=(E_{max}-E_{u})\cdot f_{s}$

Evaporation saturated zone $E_{s}=max(0.0,min(E_{p,s},d_{s}\cdot f_{gw},d_{r}\cdot f_{gw}$

Evaporation total is the sum of evaporation in the saturated and unsaturated zone:

$E=E_{u}+E_{s}$

where

b_{s}

is the datum height of the surface.

w_{g,t}

is the ground water level (datum height) at time t.

d_{gw,t}

is the depth of the ground water level, which is equal to the column height of the unsaturated zone at time t.

f_{t}

is the transpiration factor of the buildings (plants) on the surface, or the surface terrain's

[Terrain_water_evaporation_factor_(Water_Overlay)|transpiration factor]] if none present.

E_{w,t}

is the evaporation rate of the weather at time t

f_{o}

is the feddes oxygen stress factor, calculated using the 3rd and 4th root depths and the feddes trapezium interpolation model and the ground water depth.

f_{s}

is the feddes saturated zone root update factor, calculated using the 1st and 2nd root depths and the feddes trapezium interpolation model and the ground water depth.

d_{r,n}

is the nth root depth value.

E_{max}

is the potential max evaporation

E_{u}

is the evaporation in the unsaturated zone

E_{p,s}

is the potential evaporation in the saturated zone

E_{s}

is the evaporation in the saturated zone

d_{gb}

is the ground bottom distance

d_{s}

is the column height of the saturated zone covered by the roots

@@ Line 27: / Line 27: @@
 Max potential evaporation:
-<math>E_{max} = f_t \cdot E_w \cdot f_o</math>
+<math>E_{max} = f_t \cdot E_{w,t} \cdot f_o</math>
 Evaporation unsaturated:
@@ Line 33: / Line 33: @@
 <math>E_{u} =
 \begin{cases}
-.0 & \text{if } d_{us} \text{ is } \geq 0.0 \\
+.0 & \text{if } d_{gw,t} \text{ is } \geq 0.0 \\
 min(E_{max}, h_u \cdot \frac{d_{r,1}}{d_{gw,t}}) & \text{otherwise} \\
 \end{cases}
 </math>
-Evaporation saturated:
+Potential evaporation saturated:
-<math>h_{s} = w_{g,t} - ( b_{s} - d_{gb} )</math>
+<math>d_{s} = w_{g,t} - ( b_{s} - d_{gb} )</math>
-<math>h_{r} = max( 0.0 ,  w_{g,t} - ( b_{s} - d_{r,1} ))</math>
+<math>d_{r} = max( 0.0 ,  w_{g,t} - ( b_{s} - d_{r,1} ))</math>
-<math>E_{sp} = (E_{max} - E_{u}) \cdot f_s</math>
+<math>E_{p,s} = (E_{max} - E_{u}) \cdot f_s</math>
-<math>E_{s} = max (0.0 , min ( E_{sp}, h_{s}\cdot f_{gw}, h_r \cdot f_{gw}</math>
+Evaporation saturated zone
+<math>E_{s} = max (0.0 , min ( E_{p,s}, d_{s}\cdot f_{gw}, d_r \cdot f_{gw}</math>
 Evaporation total is the sum of evaporation in the saturated and unsaturated zone:
@@ Line 54: / Line 55: @@
 where
 : <math>b_{s}</math> is the datum height of the surface.
-: <math>w_{g}</math> is the underground water level.
+: <math>w_{g,t}</math> is the ground water level (datum height) at time t.
-: <math>d</math> is the column height of the unsaturated zone.
+: <math>d_{gw,t}</math> is the depth of the ground water level, which is equal to the column height of the unsaturated zone at time t.
 : <math>f_t</math> is the [[Water evaporation factor (Water Overlay)|transpiration factor]] of the buildings (plants) on the surface, or the surface terrain's
 [Terrain_water_evaporation_factor_(Water_Overlay)|transpiration factor]] if none present.
 : <math>E_{w,t}</math> is the [[Evaporation_m_(Water_Overlay)|evaporation rate]] of the [[weather]] at time t
-: <math>f_0</math> is the feddes oxygen stress factor, calculated using the 3rd and 4th [[root depths (Water Overlay)|root depths]] and the feddes trapezium interpolation model and the ground water depth.
+: <math>f_o</math> is the feddes oxygen stress factor, calculated using the 3rd and 4th [[root depths (Water Overlay)|root depths]] and the feddes trapezium interpolation model and the ground water depth.
+: <math>f_s</math> is the feddes saturated zone root update factor, calculated using the 1st and 2nd [[root depths (Water Overlay)|root depths]] and the feddes trapezium interpolation model and the ground water depth.
+: <math>d_{r,n}</math> is the nth [[root depths (Water Overlay)|root depth value]].
+: <math>E_{max}</math> is the potential max evaporation
+: <math>E_{u}</math> is the evaporation in the unsaturated zone
+: <math>E_{p,s}</math> is the potential evaporation in the saturated zone
+: <math>E_{s}</math> is the evaporation in the saturated zone
+: <math>d_{gb}</math> is the [[ground bottom distance]]
+: <math>d_{s}</math> is the column height of the saturated zone covered by the roots
 ==Related==

Ground evaporation formula (Water Overlay): Difference between revisions

Revision as of 13:33, 25 February 2021

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