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Evapotranspiration (version 1.9)

ET.SzilagyiJozsa: Szilagyi-Jozsa Formulation

Description

Implementing the Szilagyi-Jozsa formulation for estimating actual evapotranspiration

Usage

## S3 method for class 'SzilagyiJozsa':
ET(data, constants, ts="daily", solar="sunshine hours", wind="yes", 
windfunction_ver=1948, alpha=0.23, z0=0.2, \dots)

Arguments

data
A list of data which contains the following items (climate variables) required by Szilagyi-Jozsa formulation: Tmax, Tmin, RHmax, RHmin, Rs or n or Cd, u2 or uz
constants
A list named constants consists of constants required for the calculation of Szilagyi-Jozsa formulation which must contain the following items: Elev - ground elevation above mean sea level in m, lambda - latent heat of vapor
ts
Must be either daily, monthly or annual, which indicates the disired time step that the output ET estimates should be on. Default is daily.
solar
Must be either data, sunshine hours, cloud or monthly precipitation: data indicates that solar radiation data is to be used directly for calculating evapotranspiration; sunshine hours
wind
Must be either yes or no. yes indicates that the calculation will use real data of wind speed; no indicates that the alternative calculation without using wind data will be used in Penman formulation (V
windfunction_ver
The version of Penman wind function that will be used within the Penman formulation. Must be either 1948 or 1956. 1948 is for applying the Penman's 1948 wind function (Penman, 1948); 1956 is for applyi
alpha
Any numeric value between 0 and 1 (dimensionless), albedo of evaporative surface representing the portion of the incident radiation that is reflected back at the surface. Default is 0.23 for short reference crop.
z0
Any value (metres), roughness height of the evaporative surface. Default is 0.23 for short reference crop.
...
Dummy for generic function, no need to define.

Value

  • The function prints a calculation summary to the screen containing the following elements: - ET model name and ET quantity estimated - Evaporative surface with values of albedo, as well as the roughness height - Option for calculating solar radiation (i.e. the value of argument solar) - If actual wind data has been used for calculation (i.e. the value of argument wind) and which version of Penman wind function has been used (i.e. the value of argument windfunction_ver) - Time step of the output ET estimates (i.e. the value of argument ts) - Units of the output ET estimates - Time duration of the ET estimation - Number of ET estimates obtained in the entire time-series - Basic statistics of the estimated ET time-series including mean, max and min values. The function also generates a list containing the following components, which is saved into a csv file named as ET_SzilagyiJozsa.csv in the working directory:
  • ET.DailyDaily aggregated estimations of Szilagyi-Jozsa actual evapotranspiration.
  • ET.MonthlyMonthly aggregated estimations of Szilagyi-Jozsa actual evapotranspiration.
  • ET.AnnualAnnually aggregated estimations of Szilagyi-Jozsa actual evapotranspiration.
  • ET.MonthlyAveMonthly averaged estimations of daily Szilagyi-Jozsa actual evapotranspiration.
  • ET.AnnualAveAnnually averaged estimations of daily Szilagyi-Jozsa actual evapotranspiration.
  • ET_formulationName of the formulation used which equals to Szilagyi-Jozsa.
  • ET_typeA character string containing the type of the estimation obtained which is Actual Evapotranspiration.
  • message1A message to inform the users about how solar radiation has been calculated by using which data.
  • message2A message to inform the users about if actual wind data has been used in the calculations or alternative calculations has been performed without wind data, and which version of the Penman wind function has been used.

Details

The alternative calculation options can be selected through arguments solar, wind and windfunction_ver, please see Arguments for details. User-defined evaporative surface is allowed through arguments alpha and z0, please see Arguments for details.

References

Szilagyi, J. 2007. On the inherent asymmetric nature of the complementary relationship of evaporation. Geophysical Research Letters, 34, L02405. McMahon, T., Peel, M., Lowe, L., Srikanthan, R. & McVicar, T. 2012. Estimating actual, potential, reference crop and pan evaporation using standard meteorological data: a pragmatic synthesis. Hydrology and Earth System Sciences Discussions, 9, 11829-11910. Penman, H. L. 1948. Natural evaporation from open water, bare soil and grass. Proceedings of the Royal Society of London. Series A. Mathematical and Physical Sciences, 193, 120-145. Valiantzas, J. D. 2006. Simplified versions for the Penman evaporation equation using routine weather data. Journal of Hydrology, 331, 690-702. Penman, H. L. 1956. Evaporation: An introductory survey. Netherlands Journal of Agricultural Science, 4, 9-29.

See Also

ET,data,defaultconstants,constants,ET.Penman

Examples

Run this code
# Use processed existing data set and constants from kent Town, Adelaide
data("processeddata")
data("constants")

# Call ET.SzilagyiJozsa under the generic function ET
results <- ET.SzilagyiJozsa(data, constants, ts="daily", 
solar="sunshine hours", wind="yes", windfunction_ver=1948, alpha=0.23, z0=0.2)

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