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PowerSDI

Calculates the Standardised Precipitation (SPI) and Standardised Precipitation-Evapotranspiration (SPEI) indices using NASA POWER data.

Basic Description

The PowerSDI is an R package capable of calculating the SPI and SPEI using NASA POWER data. The package is based on five R-functions designed to calculate these two standardised drought indices (SDI) in scientific and operational/routine modes. The functions ScientSDI(), Accuracy(), Reference() and, PlotData() may be used to assess, among other features, the ability of the SPI and SPEI frequency distributions to meet the normality assumption and how well NASA POWER estimates represent “real-world” data. The OperatSDI() function calculates both SPI and SPEI in an operational mode.

The PowerSDI adopts a basic time scale that splits each month into four subperiods: days 1 to 7, days 8 to 14, days 15 to 21, and days 22 to 28, 29, 30, or 31 depending on the month. For instance, if TS=4, the time scale corresponds to a moving window with a 1-month length that is calculated four times each month. If TS=48, the time scale corresponds to a moving window with a 12-month length that is calculated four times each month. This time scale is referred to as “quart.month”.

The package depends on R (>= 3.10) and R packages {nasapower} and {lmom}.

Installation

devtools::install_github("gabrielblain/PowerSDI")

Basic Instructions

Function ScientSDI()

Helps the users to verify if the SPI and SPEI calculated from NASA POWER data meet the conceptual assumptions expected from standardised drought indices.

Usage

ScientSDI(
  lon,
  lat,
  start.date,
  end.date,
  distr = "GEV",
  TS = 4,
  Good = "Yes",
  sig.level = 0.95,
  RainUplim = NULL,
  RainLowlim = NULL,
  PEUplim = NULL,
  PELowlim = NULL
)

Arguments

Value

A list with data calculated at the time scale selected by the user. If Good="Yes", this list includes:

If Good="No", this list includes: * SDI and * DistPar.

This function also presents other data (in millimetres) calculated from the NASA POWER project:

Examples

ScientSDI(
  lon = -47.3,
  lat = -22.67,
  start.date = "1991-01-01",
  end.date = "2022-12-31"
)

Function Accuracy()

Verifies how well NASA-POWER data actually represent real-world/observed data.

Usage

Accuracy(obs_est, conf.int = "Yes", sig.level = 0.95)

Arguments

Value

Examples

data("ObsEst")
Accuracy(obs_est = ObsEst, conf.int = "Yes", sig.level = 0.95)

Function OperatSDI()

Generates routine operational NASA-SPI and NASA-SPEI estimates in several regions and at distinct time scales.

Usage

OperatSDI(
  lon,
  lat,
  start.date,
  end.date,
  PEMethod = "HS",
  distr = "GEV",
  parms,
  TS = 4
)

Arguments

Value

A data frame with:

Examples

data("DistPar")
OperatSDI(
  lon = -47.3,
  lat = -22.67,
  start.date = "2023-01-31",
  end.date = "2023-07-07",
  parms = DistPar
)

Function PlotData()

Generates scatter plots of rainfall and accumulated potential evapotranspiration.

Usage

PlotData(lon, lat, start.date, end.date)

Arguments

Value

Scatter plots of: * Rainfall and * potential evapotranspiration accumulated at the 1-quart.month time scale.

Examples

PlotData(
  lon = -47.3,
  lat = -22.87,
  start.date = "2021-12-28",
  end.date = "2022-12-31"
)

Function Reference()

Calculates both SPI and SPEI from daily data obtained from a ground weather station or any other reference source.

Usage

Reference(ref, distr = "GEV", PEMethod = "HS", TS = 4)

Arguments

Value

A data frame with: * Rain, * potential evapotranspiration, * difference between rainfall and potential evapotranspiration, * SPI and SPEI calculated at the time scale selected by the user.

Examples

data("refHS")
Reference(ref = refHS, distr = "GEV, PEMethod = "HS", TS = 4)

DistPar: parameters for calculating the SDIs. Provided by the ScientSDI function.

Contains parameters of the gamma and GEV distributions and the Pr(Rain=0).

Usage

DistPar

Format

Source

Generated by the ScientSDI() function using NASA POWER data.

Examples

data(DistPar)

ObsEst: Example of the input required by the Accuracy function.

Contains pairs of reference and estimated data.

Usage

ObsEst

Format

Source

Generated by the PowerSDI package using data from the NASA POWER and Agronomic Institute.

Examples

data(ObsEst)

refHS: Example of the input required by the Reference function

Contains data for calculating the SPI and SPEI.

Usage

refHS

Format

An 8-column matrix with 10950 rows and 8 variables

Source

Agronomic Institute and NASA POWER

Examples

data(refHS)

refPM: Example of the input required by the Reference function

Contains data for calculating the SPI and SPEI.

Usage

refPM

Format

A 11-column matrix with 10958 rows and 11 variables

Source

Agronomic Institute and NASA POWER

Examples

data(refPM)

BugReports:

https://github.com/gabrielblain/PowerSDI/issues

License:

MIT

Authors:

Gabriel Constantino Blain, Graciela da Rocha Sobierajski, Leticia Lopes Martins, and Adam H Sparks Maintainer: Gabriel Constantino Blain, gabriel.blain@sp.gov.br

Acknowledgments:

The package uses data obtained from the NASA Langley Research Center (LaRC) POWER Project funded through the NASA Earth Science/Applied Science Program. The POWER project provides data for support several activities including agriculture and energy. The authors greatly appreciate this initiative.

References

Allen, R.G.; Pereira, L.S.; Raes, D.; Smith, M. Crop evapotranspiration. In Guidelines for Computing Crop Water Requirements. Irrigation and Drainage Paper 56; FAO: Rome, Italy, 1998; p. 300.

Blain, G. C., 2014. Revisiting the critical values of the Lilliefors test: towards the correct agrometeorological use of the Kolmogorov- Smirnov framework. Bragantia, 73, 192-202. http://dx.doi.org/10.1590/brag.2014.015

Hargreaves, G.H.; Samani, Z.A. 1985.Reference crop evapotranspiration from temperature. Appl. Eng. Agric,1, 96–99.

Mckee, T. B., Doesken, N.J. and Kleist, J., 1993. The relationship of drought frequency and duration to time scales. In: 8th Conference on Applied Climatology. Boston, MA: American Meteorological Society, 179–184.

Stagge, J. H., Tallaksen, L. M., Gudmundsson, L., Van Loon, A. F. and Stahl, K., 2015. Candidate distribution for climatological drought indices (SPI and SPEI). International Journal of Climatology, 35(13), 4027–4040. https://doi.org/10.1002/joc.4267

Package ‘lmom’, Version 2.9, Author J. R. M. Hosking. https://CRAN.R-project.org/package=lmom

Package ‘nasapower’, Version 4.0.10, Author Adam H. Sparks et al., https://CRAN.R-project.org/package=nasapower

Wu, H., Svoboda, M. D., Hayes, M. J., Wilhite, D. A. and Wen, F., 2006. Appropriate application of the standardised precipitation index in arid locations and dry seasons. International Journal of Climatology, 27(1), 65–79. https://doi.org/10.1002/joc.1371.

These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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