rsaga.pisr2: Potential incoming solar radiation SAGA 2.2.2+
In debangs/RSAGA: SAGA Geoprocessing and Terrain Analysis in R

Description Usage Arguments Details Note Author(s) References See Also

This function calculates the potential incoming solar radiation in an area using different atmospheric models; This function reflects changes to the module with SAGA 2.2.2+. For SAGA versions 2.0.6 to 2.2.1 please see rsaga.pisr.

rsaga.pisr2(in.dem, in.svf.grid = NULL, in.vapour.grid = NULL,
  in.linke.grid = NULL, out.direct.grid, out.diffuse.grid,
  out.total.grid = NULL, out.ratio.grid = NULL, out.duration, out.sunrise,
  out.sunset, local.svf = TRUE, location = c("latitude", "grid"),
  latitude = 53, unit = c("kWh/m2", "kJ/m2", "J/cm2"), solconst = 1367,
  method = c("height", "components", "lumped", "hofierka"),
  hgt.atmosphere = 12000, cmp.pressure = 1013, cmp.water.content = 1.68,
  cmp.dust = 100, lmp.transmittance = 70, time.range = c(0, 24),
  time.step = 0.5, start.date = list(day = 31, month = 10, year = 2015),
  end.date = NULL, day.step = 5, env = rsaga.env(), ...)

`in.dem`	name of input digital elevation model (DEM) grid in SAGA grid format (default extension: `.sgrd`)
`in.svf.grid`	Optional input grid in SAGA format: Sky View Factor; see also `local.svf`
`in.vapour.grid`	Optional input grid in SAGA format: Water vapour pressure (mbar), for use with `method = "height"`; default 10 mbar
`in.linke.grid`	Optional input grid in SAGA format: Linke turbidity coefficient, for use with `method = "hofierka"`; default 3.0
`out.direct.grid`	Output grid: Direct insolation (unit selected by `unit` argument)
`out.diffuse.grid`	Output grid: Diffuse insolation
`out.total.grid`	Optional output grid: Total insolation, i.e. sum of direct and diffuse incoming solar radiation
`out.ratio.grid`	Optional output grid: Direct to diffuse ratio
`out.duration`	Optional output grid: Duration of insolation
`out.sunrise`	Optional output grid: time of sunrise; only calculated if time span is set to single day
`out.sunset`	Time of sunset; see `out.sunrise`
`local.svf`	logical (default: `TRUE`; if TRUE, use sky view factor based on local slope (after Oke, 1988), if no sky view factor grid is provided in `in.svf.grid`
`location`	specified whether to use constant latitude supplied by `latitude` below (`"latitude"` or code `0`; default) or as calculated from the grid system (`"grid"` or code `1`)
`latitude`	Geographical latitude in degree North (negative values indicate southern hemisphere)
`unit`	unit of insolation output grids: `"kWh/m2"` (default) `"kJ/m2"`, or `"J/cm2"`
`solconst`	solar constant, defaults to 1367 W/m2
`method`	specifies how the atmospheric components should be accounted for: either based on the height of atmosphere and vapour pressure (`"height"`, or numeric code 0), or air pressure, water and dust content (`"components"`, code 1), or lumped atmospheric transmittance (`"lumped"`, code `2`), or by the method of Hofierka and Suri, 2009 (`"hofierka"`, code `3`). Default: `"lumped"`.
`hgt.atmosphere`	Height of atmosphere (in m); default 12000 m. For use with `method = "height"`
`cmp.pressure`	atmospheric pressure in mbar, defaults to 1013 mbar. For use with `method = "components"`
`cmp.water.content`	water content of a vertical slice of the atmosphere in cm: between 1.5 and 1.7cm, average 1.68cm (default). For use with `method = "components"`
`cmp.dust`	dust factor in ppm; defaults to 100 ppm. For use with `method = "components"`
`lmp.transmittance`	transmittance of the atmosphere in percent; usually between 60 (humid areas) and 80 percent (deserts)
`time.range`	numeric vector of length 2: time span (hours of the day) for numerical integration
`time.step`	time step in hours for numerical integration
`start.date`	list of length three, giving the start date in `day`, `month`, and `year` components as numbers; month is one-based (SAGA_CMD uses zero-based numbers internally), i.e. Jan. 1st 2015 is `list(day=1,month=1,year=2015)`
`end.date`	see `start.date`
`day.step`	if `days` indicates a range of days, this specifies the time step (number of days) for calculating the incoming solar radiation
`env`	RSAGA geoprocessing environment obtained with `rsaga.env`; this argument is required for version control (see Note)
`...`	optional arguments to be passed to `rsaga.geoprocessor`

According to SAGA GIS 2.0.7 documentation, "Most options should do well, but TAPES-G based diffuse irradiance calculation ("Atmospheric Effects" methods 2 and 3) needs further revision!" I.e. be careful with method = "components" and method = "lumped".

SAGA_CMD uses zero-based months, but this R function uses the standard one-based months (e.g. day 1 is the first day of the month, month 1 is January) and translates to the SAGA system.

This function uses module Potential Incoming Solar Radiation from SAGA library ta_lighting in SAGA version 2.0.6+. Changes to the module with SAGA 2.2.2+ include adding year to the *.date arguments to allow calculation across years. The method of Hofierka and Suri (2009) is added, which uses the Linke turbidity coefficient. Duration of insolation ("out.duration") is only calculated when the time period is set to a single day.

Alexander Brenning & Donovan Bangs (R interface), Olaf Conrad (SAGA module)

Boehner, J., Antonic, O. (2009): Land surface parameters specific to topo-climatology. In: Hengl, T. and Reuter, H. I. (eds.): Geomorphometry - Concepts, Software, Applications. Elsevier.

Oke, T.R. (1988): Boundary layer climates. London, Taylor and Francis.

Wilson, J.P., Gallant, J.C. (eds.), 2000: Terrain analysis - principles and applications. New York, John Wiley and Sons.

Hofierka, J., Suri, M. (2002): The solar radiation model for Open source GIS: implementation and applications. International GRASS users conference in Trento, Italy, September 2002

rsaga.pisr; for similar modules in older SAGA versions (pre-2.0.6) see rsaga.solar.radiation and rsaga.insolation; rsaga.hillshade

debangs/RSAGA documentation built on May 15, 2019, 1:53 a.m.