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| - | ==1.4. Crop forecasting with water budget calculations. == | + | ==1.4. Crop yield forecasting with water balance calculations. == |
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| + | {| style="background-color:#F5F5F5; border-collapse:collapse" cellspacing="7" border="1" bordercolorlight="#0000FF" bordercolordark="#0000FF"> | ||
| + | |style="border-style: solid; border-width: 1px"|''Clarance Sakamoto, René Gommes, Peter Hoefsloot'' | ||
| + | |- | ||
| + | |} | ||
| ===Crop water use=== | ===Crop water use=== | ||
| - | + | Evapotranspiration is the combination of two separate processes whereby water is lost on the one hand from the soil surface by ''evaporation'' and on the other hand from the crop by ''transpiration''. During the crop season the crop canopy will increase. This is usually expressed through the Leaf Arae Index (LAI). This denotes the number of times that the total leaf surface area of the crop exceeds the ground surface area the plants cover. A typical course of the LAI during the season can be seen in the graph below. During the season the relative importance of evaporation of the soil decreases versus the crop transpiration. | |
| - | Evapotranspiration is the combination of two separate processes whereby water is lost on the one hand from the soil surface by ''evaporation'' and on the other hand from the crop by ''transpiration''. During the crop season the crop canopy will increase. This is usually expressed through the Leaf Arae Index (LAI). This denotes the number of times that the total leaf surface area of the crop exceeds the ground area the plants cover. A typical course of the LAI during the season can be seen in the graph below. During the season the relative importance of evaporation of the soil decreases versus the crop transpiration. | + | |
| - | + | ||
| {|"class=prettytable" cellpadding="15" border="1" style="border-collapse:collapse" | {|"class=prettytable" cellpadding="15" border="1" style="border-collapse:collapse" | ||
| - | |width="225"|Typical course of LAI during season||[[Image:graph1.jpg|500px|]] | + | |width="225"|Typical course of crop transpiration (linked to LAI) and the soil evaporation during the season||[[Image:graph1.jpg|500px|]] |
| |} | |} | ||
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| ===Relation between crop water use and yield=== | ===Relation between crop water use and yield=== | ||
| - | + | Doorenbos and Kassam outlined in their FAO publication “Yield response to water” that there is a clear relation between crop yield and water use. This relation is the basis of the use of a water balance calculation in crop forecasting. It is possible to establish a maximum yield (Y<sub>m</sub>) based on a season without water stress and water deficit. The total evapotranspiration is then at his maximum (ET<sub>m</sub>). In semi-arid circumstances yield is usually reduced due to water stress leading to a lower actual yield (Y<sub>a</sub>) and lower actual evapotranspiration (ET<sub>a</sub>) | |
| - | Doorenbos and Kassam outlined in their FAO publication “Yield response to water” that there is a clear relation between crop yield and water use. This relation is the basis of the use of a water balance calculation in crop forecasting. It is possible to establish a maximum yield (Ym) based on a season without water stress and water deficit. The total evapotranspiration is then at his maximum (ETm). In semi-arid circumstances yield is usually reduced due to water stress leading to a lower actual yield (Ya) and lower evapotranspiration (ETa) | + | |
| ===Yield response to water=== | ===Yield response to water=== | ||
| - | The authors introduced the so-called yield response factor (ky) to explain the yield reduction due to water stress. They established the yield response factor for a large number of crops in a limited number of climates. Doorenbos and Kassam found this relation to be near-linear for most crops (see graph). The general formula is: | + | The authors introduced the so-called yield response factor (k<sub>y</sub>) to explain the yield reduction due to water stress. They established the yield response factor for a large number of crops in a limited number of climates. Doorenbos and Kassam found this relation to be near-linear for most crops (see graph). The general formula is: |
| - | (1- Ya/Ym) = ky * (1 - ETa/ETm) | + | (1- Y<sub>a</sub>/Y<sub>m</sub>) = k<sub>y</sub> * (1 - ET<sub>a</sub>/ET<sub>m</sub>) |
| The graph below establishes the relationship for a number of crops. | The graph below establishes the relationship for a number of crops. | ||
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| {|"class=prettytable" cellpadding="15" border="1" style="border-collapse:collapse" | {|"class=prettytable" cellpadding="15" border="1" style="border-collapse:collapse" | ||
| - | |width="225"|Relation between Yield and ETA for some crops||[[Image:graph2.jpg|500px|]] | + | |width="225"|Relation between Yield and ET<sub>a</sub> for some crops||[[Image:graph2.jpg|500px|]] |
| |} | |} | ||
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| ===Actual and reference evapotranspiration=== | ===Actual and reference evapotranspiration=== | ||
| - | Summarizing, crop yield can be estimated by measuring actual evapotranspiration. The only reliable way of measuring actual evapotranspiration is to use large containers (sometimes on the order of several metres across) called lysimeters, evaluate the different components of the water balance precisely, and calculate the evapotranspiration by subtraction. | + | Summarizing, crop yield can be estimated by measuring actual evapotranspiration. The only reliable way of measuring actual evapotranspiration is to use large containers (sometimes on the order of several meters across) called lysimeters, evaluate the different components of the water balance precisely, and calculate the evapotranspiration by subtraction. |
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| - | Installing lysimeters is vast quantities is impractical, but through the work of Penman (1948) and Monteith (1980). Through experimentation Penman found that that it was possible to calculate a “crop neutral” reference evapotranspiration (ET0) based on 4 basic meteorological parameters: | + | Installing lysimeters is vast quantities is impractical. However, through experimentation Penman found that that it was possible to calculate a “crop neutral” reference evapotranspiration (ET0) based on 4 basic meteorological parameters: |
| * Wind | * Wind | ||
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| * Humidity | * Humidity | ||
| - | Some of these input 4 parameters can be estimated from others. Many meteorological stations around the world measure these parameters making it possible to calculate ET0. | + | Many meteorological stations around the world measure these parameters making it possible to calculate ET0. Some of these input 4 parameters can be estimated from others. |
| - | Reference evapotranspiration (ETo or sometimes referred to as potential evapotranspiration) is defined as the evapotranspiration from a 10cm tall grass that completely covers the ground, and is supplied with adequate water. Many scientists refined Penman’s work. FAO has standardized on the adaptations by Montheith (1980). | + | Reference evapotranspiration (ETo or sometimes referred to as potential evapotranspiration) is defined as the evapotranspiration from a 10cm tall grass that completely covers the ground, and is supplied with adequate water. Many scientists refined Penman’s work. FAO has standardized on the adaptations by Montheith. |
| - | + | ||
| - | ===An example : calculating the ET0 in AgrometShell.=== | + | |
| - | + | ||
| - | < still to do > | + | |
| ===Crop coefficients=== | ===Crop coefficients=== | ||
| + | The relation between actual and reference evapotranspiration and actual evaporation in the field is based on crop coefficients. ET<sub>a</sub> is determined by the crop coefficient approach whereby the effect of the various weather conditions are incorporated into ET<sub>0</sub> and the crop characteristics into the K<sub>c</sub> coefficient: | ||
| - | The relation between actual and reference evapotranspiration and actual evaporation in the field is based on crop coefficients. ETa is determined by the crop coefficient approach whereby the effect of the various weather conditions are incorporated into ETo and the crop characteristics into the Kc coefficient: | + | ET<sub>a</sub> = K<sub>c</sub> * ET<sub>0</sub> |
| - | ETa = Kc * ETo | + | The effect of both crop transpiration and soil evaporation are integrated into a single crop coefficient. In other words, the K<sub>c</sub> coefficient incorporates crop characteristics and averaged effects of evaporation from the soil. |
| - | The effect of both crop transpiration and soil evaporation are integrated into a single crop coefficient. In other words, the Kc coefficient incorporates crop characteristics and averaged effects of evaporation from the soil. | + | Crop coefficients (K<sub>c</sub>) are dependent on: |
| - | + | ||
| - | Crop coefficients (Kc) are dependent on: | + | |
| * Crop | * Crop | ||
| * Phenological stage of the crop (planting, vegetative phase, yield formation, ripening etc..) | * Phenological stage of the crop (planting, vegetative phase, yield formation, ripening etc..) | ||
| * Soils, climate etc. Crop coefficients are known to be slightly different for different parts of the world. | * Soils, climate etc. Crop coefficients are known to be slightly different for different parts of the world. | ||
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| - | ===An example : examining the crop coefficients implementing in AgrometShell.=== | ||
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| - | Using the “Database – Configure - Crop Coefficients“ of Agrometshell the crop coefficients can be viewed and (if needed) adapted to local circumstances. | ||
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| - | {|"class=prettytable" cellpadding="15" border="1" style="border-collapse:collapse" | ||
| - | |width="225"|Defining crop coeficients in AgrometShell||[[Image:graph4.jpg|400px|]] | ||
| - | |} | ||
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| - | In this screen the crop coefficients are defined per crop and phenological phase. Different sets of coefficients can be defined per crop. Rather than working with fixed crop cycles, this screen defines the coefficnts for a certain % of crop cycle. The left set of the window allows manipulation of the curve on the right side. | ||
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| </blockquote> | </blockquote> | ||
Revision as of 13:28, 24 September 2006
1.4. Crop yield forecasting with water balance calculations.
Clarance Sakamoto, René Gommes, Peter Hoefsloot Crop water use
Evapotranspiration is the combination of two separate processes whereby water is lost on the one hand from the soil surface by evaporation and on the other hand from the crop by transpiration. During the crop season the crop canopy will increase. This is usually expressed through the Leaf Arae Index (LAI). This denotes the number of times that the total leaf surface area of the crop exceeds the ground surface area the plants cover. A typical course of the LAI during the season can be seen in the graph below. During the season the relative importance of evaporation of the soil decreases versus the crop transpiration.
Typical course of crop transpiration (linked to LAI) and the soil evaporation during the season 
Relation between crop water use and yield
Doorenbos and Kassam outlined in their FAO publication “Yield response to water” that there is a clear relation between crop yield and water use. This relation is the basis of the use of a water balance calculation in crop forecasting. It is possible to establish a maximum yield (Ym) based on a season without water stress and water deficit. The total evapotranspiration is then at his maximum (ETm). In semi-arid circumstances yield is usually reduced due to water stress leading to a lower actual yield (Ya) and lower actual evapotranspiration (ETa)
Yield response to water
The authors introduced the so-called yield response factor (ky) to explain the yield reduction due to water stress. They established the yield response factor for a large number of crops in a limited number of climates. Doorenbos and Kassam found this relation to be near-linear for most crops (see graph). The general formula is:
(1- Ya/Ym) = ky * (1 - ETa/ETm)
The graph below establishes the relationship for a number of crops.
Relation between Yield and ETa for some crops 
Actual and reference evapotranspiration
Summarizing, crop yield can be estimated by measuring actual evapotranspiration. The only reliable way of measuring actual evapotranspiration is to use large containers (sometimes on the order of several meters across) called lysimeters, evaluate the different components of the water balance precisely, and calculate the evapotranspiration by subtraction.
A lysimeter 
Installing lysimeters is vast quantities is impractical. However, through experimentation Penman found that that it was possible to calculate a “crop neutral” reference evapotranspiration (ET0) based on 4 basic meteorological parameters:
- Wind
- Solar radiation
- Temperature
- Humidity
Many meteorological stations around the world measure these parameters making it possible to calculate ET0. Some of these input 4 parameters can be estimated from others.
Reference evapotranspiration (ETo or sometimes referred to as potential evapotranspiration) is defined as the evapotranspiration from a 10cm tall grass that completely covers the ground, and is supplied with adequate water. Many scientists refined Penman’s work. FAO has standardized on the adaptations by Montheith.
Crop coefficients
The relation between actual and reference evapotranspiration and actual evaporation in the field is based on crop coefficients. ETa is determined by the crop coefficient approach whereby the effect of the various weather conditions are incorporated into ET0 and the crop characteristics into the Kc coefficient:
ETa = Kc * ET0
The effect of both crop transpiration and soil evaporation are integrated into a single crop coefficient. In other words, the Kc coefficient incorporates crop characteristics and averaged effects of evaporation from the soil.
Crop coefficients (Kc) are dependent on:
- Crop
- Phenological stage of the crop (planting, vegetative phase, yield formation, ripening etc..)
- Soils, climate etc. Crop coefficients are known to be slightly different for different parts of the world.
