--- title: "User Guide: 2 Astronomy and Atmosphere" subtitle: "Package 'photobiology' `r packageVersion('photobiology')` " author: "Pedro J. Aphalo" date: "`r packageDate('photobiology')`" output: rmarkdown::html_vignette: toc: yes vignette: > %\VignetteIndexEntry{User Guide: 2 Astronomy and Atmosphere} %\VignetteEngine{knitr::rmarkdown} %\VignetteEncoding{UTF-8} --- ## Radiation, astronomy and atmosphere The User Guide is divided into two volumes: _1. Radiation_ and _2. Astronomy_. The second volume also describes functions related to water vapour in the atmosphere. ```{r, include=FALSE, echo=FALSE} knitr::opts_chunk$set(fig.width=8, fig.height=4) ``` ```{r, printing-spectra, eval=TRUE, include=FALSE} # library(tibble) options(tibble.print_max = 6, tibble.print_min = 4) ``` ## Getting started We load two packages, our '**photobiology**' and '**lubridate**', as they will be used in the examples. ```{r, pkg-load, eval=TRUE, message = FALSE} library(photobiology) library(lubridate) # if installed, we use 'lutz' to lookup time zones from geocodes eval_lutz <- requireNamespace("lutz", quietly = TRUE) if (eval_lutz) {library(lutz)} ``` ## Introduction Most organisms, including plants and animals, have circadian internal clocks. These clocks are entrained to the day-night cycle through perception of light. For example, night length informs plants about seasons of the year. This information allows the synchronization of developmental events like flowering to take place at the "right" time of the year. From the point of view of interactions between light and vegetation, the direction of the direct light beam is of interest. Hence, the position of the sun in the sky is also important for photobiology. This is the reason for the inclusion of astronomical calculations about the sun in this package. On the other hand, such calculations are also highly relevant to other fields including solar energy. The functions and methods described in this volume return either values that represent angles or times. In the current version angles are always expressed in degrees. In the case of times, the unit of expression, can be changed through parameter `unit.out` which accepts the following arguments `"datetime"`, `"hours"`, `"minutes"`, `"seconds"`. For backwards compatibility `"date"` is also accepted as equivalent to `"datetime"` but deprecated. All astronomical computations rely on the algorithms of Meuss (1998), and consequently returned values are very precise. However, these algorithms are computationally rather costly. Contrary to other faster algorithms, they give reliable estimates even for latitudes near the poles. However, at high latitudes due to the almost tangential path of the sun to the horizon, atmospheric effects that slightly alter the apparent elevation of the sun have much larger effects on the apparent timing of events given that the solar elevation angle changes at a slower rate than at lower latitudes. ## Position of the sun The position of the sun at an arbitrary geographic locations and time instant can be described with two angles: elevation above the horizon and azimuth angle relative to the geographic North. If expressed in degrees, solar elevation ($h$) varies between -90 and 90 degrees, while being visible when angles are positive and otherwise occluded below the horizon. Azimuth angle ($\alpha$) varies clockwise from North between 0 and 360 degrees. Zenith angle ($z$), provides the same information as the elevation angle but using the zenith as starting point, consequently taking values between 0 and 180 degrees, such that $z = 90 - h$. Declination angle describes the angle between the plane of the Equator and the plane of the Earth's orbit around the sun, and varies with the seasons of the year. The function `sun_angles` returns location, civil time, local solar time, the azimuth in degrees eastwards, elevation in degrees above the horizon, declination, the equation of time and the hour angle. ---- In versions up to 0.9.11 in addition to parameter `geocode` most functions also had the redundant formal parameters `lon` and `lat` which were removed in version 0.9.12. This change may require users' scripts to be revised. ---- In versions 0.9.16 and later the code has been optimized for performance with time vectors, making massive calculations such as the sun position for every minute of the year quite fast (couple of seconds). We keep, however, examples with rather short vectors. ---- For calculation of the position of the sun we need to supply geographic coordinates and a time instant. The time instant passed as argument should be a `POSIXct` vector, possibly of length one. The easiest way create date and time constant values is to use package 'lubridate'. The object to be supplied as argument for `geocode` is a data frame with variables `lon` and `lat` giving the location on Earth. This matches the return value of functions `tidygeocoder::geo_osm()`, `tidygeocoder::geo_google()` and `ggmap::geocode()`, functions that can be used to find the coordinates using an _address_ entered as a character string understood by the OSM or Google maps APIs (Google requires an API key and registration, while OSM is open). We use the "geocode" for Helsinki, defined explicitly rather than searched for. ```{r} my.geocode <- data.frame(lat = 60.16, lon = 24.93, address = "Helsinki") ``` Be aware that to obtain correct the time zone must be correctly set for the argument passed to `time`. To obtain results based on local time, this time zone needs to be set in the `POSIXct` object or passed as a argument to `tz`. In the examples we use functions from package 'lubridate' for working with times and dates. The argument passed to parameter `time` can be a "vector" of `POSIXct` values. The returned value is a `data.frame`. The position of the sun at Helsinki, at the given instant in time for time zone _Eastern European Time_. ```{r} sun_angles(time = ymd_hms("2017-06-20 08:00:00", tz = "EET"), geocode = my.geocode) ``` Functions have defaults for their arguments, but rarely Greenwich will be the location you are interested in. Current UTC time is probably a useful default in some cases. ```{r} sun_angles() ``` A vector of times is accepted as argument, and as performance is optimized for this case, _vectorization_ will markedly improve performance compared to multiple calls to the function. The vector of times can be created on the fly, or stored beforehand. ```{r} sun_angles(time = ymd_hms("2014-01-01 0:0:0", tz = "EET") + hours(c(0, 6, 12)), geocode = my.geocode) ``` ```{r} my.times <- ymd_hms("2014-01-01 0:0:0", tz = "EET") + hours(c(0, 6, 12)) sun_angles(time = my.times, geocode = my.geocode) ``` Geocodes for several locations can be stored in a data frame with multiple rows. ```{r} two.geocodes <- data.frame(lat = c(60.16, 65.02), lon = c(24.93, 25.47), address = c("Helsinki", "Oulu")) sun_angles(time = my.times, geocode = two.geocodes) ``` When spectra contain suitable metadata, the position of the sun for the spectral irradiance data measurement can be easily obtained. ```{r} sun_angles(time = getWhenMeasured(sun.spct), geocode = getWhereMeasured(sun.spct)) ``` If what is needed is only one of the solar angles, functions returning vectors instead of data frames can be useful. (In their current implementation these functions _do not_ have improved performance compared to `sun_angles()`) ```{r} sun_elevation(time = my.times, geocode = my.geocode) ``` ```{r} sun_zenith_angle(time = my.times, geocode = my.geocode) ``` ```{r} sun_azimuth(time = my.times, geocode = my.geocode) ``` ## Times of sunrise, solar noon and sunset Convenience functions `sunrise_time()`, `sunset_time()`, `noon_time()`, `day_length()` and `night_length()` have all the same parameter signature and are wrappers on function `day_night()`. Function `day_night` returns a data frame containing all the quantities returned by the other functions. These functions are vectorized for their `date` and `geocode` parameters. They use as default location Greenwich in the U.K., and default time zone "UTC". The date is given by default by the current date based on "UTC". Universal Time Coordinate ("UTC") is the reference used to describe differences among time zones and is never modified by daylight saving time or summer time. The difference between EET (Eastern European Time) and UTC is +2 hours in winter and with EEST (Eastern European Summer Time) +3 hours. Latitude and longitude are passed through a `geocode` (a data frame). If the returned value is desired in the local time coordinates of the argument passed to `geocode`, the time zone should match the geographic coordinates. If geocodes contain a variable `"address"` it will be copied to the output. In some of the examples below we reuse the geocode data frames created above, and we here create a vector of datetime objects differing in their date. The default time zone of function `ymd()` is `NULL`, so we override it with `EET` to match the geocodes for Finnish cities. ```{r} dates <- ymd("2015-03-01", tz = "EET") + months(0:5) dates ``` As first example we compute the sunrise time for the current day in Helsinki, with the result returned eithe in UTC or EET coordinates. Time-zone names based on continent and city are also supported, and are to be preferred for past dates and the relationship between time zones and locations are affected by changes in country boundaries and in national laws. ```{r} sunrise_time(now("UTC"), geocode = my.geocode) sunrise_time(now("EET"), geocode = my.geocode) sunrise_time(now("Europe/Helsinki"), geocode = my.geocode) ``` ---- Be aware of the behaviour of functions `ymd()`, `dmy()`, `ym()` and `my()` from package 'lubridate'. A function call like `ymd("2015-03-01", tz = "UTC")` returns a `POSIXct` object while a call like `ymd("2015-03-01")` is equivalent to `ymd("2015-03-01", tz = NULL)` and returns a `Date` object. `Date` objects do not carry time zone information in the way `POSIXct` objects do, and consequently `Dates` do not uniquely match a period between two absolute instants in time, but rather between two instants in local time. Given these features, it is safer to use `POSIXct` objects as arguments to the functions from package 'photobiology'. Function `today()` always returns a `Date` while function `now()` always returns a `POSIXct`, independently of the argument passed to their `tzone` parameter. Consequently it is preferable to use `now()`, but if you do use `today()` make sure to path the same value as argument to parameter `tzone` of `today()` and to parameter `tz` of the functions from package 'photobiology'. _An instant in time and time zone strictly define a corresponding date at any location on Earth._ The default for time zone is that of the `POSIXct` value passed as argument to parameter `date`, but this can be overridden. ```{r} sunrise_time(geocode = my.geocode) sunrise_time(date = now("UTC"), geocode = my.geocode) sunrise_time(date = now("UTC"), tz = "UTC", geocode = my.geocode) sunrise_time(date = now("EET"), geocode = my.geocode) sunrise_time(date = now("EET"), tz = "EET", geocode = my.geocode) sunrise_time(today("EET"), tz = "EET", geocode = my.geocode) ``` ---- We can also compute the time of solar noon and of sunset. ```{r} noon_time(now("UTC"), geocode = my.geocode) noon_time(now("EET"), geocode = my.geocode) ``` ```{r} sunset_time(now("UTC"), geocode = my.geocode) sunset_time(now("EET"), geocode = my.geocode) ``` Functions `day_length()` and `night_length()` return the length of time, by default in hours and fraction. ```{r} day_length(dates, geocode = my.geocode) night_length(dates, geocode = my.geocode) ``` Southern hemisphere latitudes as well as longitudes to the West of the Greenwich meridian should be supplied as negative numbers. ```{r} sunrise_time(dates, geocode = data.frame(lat = 60, lon = 25)) noon_time(dates, geocode = data.frame(lat = 60, lon = 25)) ``` ```{r} sunrise_time(dates, geocode = data.frame(lat = -60, lon = 25)) noon_time(dates, geocode = data.frame(lat = -60, lon = 25)) ``` The angle used in the twilight calculation can be supplied, either as the name of a standard definition, or as an angle in degrees (negative for sun positions below the horizon). Positive angles can be used when the time of sun occlusion behind a building, mountain, or other obstacle needs to be calculated. The default for `twilight` is `"none"` meaning that times correspond to the occlusion of the upper rim of the sun disk below the theoretical horizon. ```{r} sunrise_time(ymd("2017-03-21", tz = "EET"), tz = "EET", geocode = my.geocode, twilight = "civil") sunrise_time(ymd("2017-03-21", tz = "EET"), tz = "EET", geocode = my.geocode, twilight = -10) sunrise_time(ymd("2017-03-21", tz = "EET"), tz = "EET", geocode = my.geocode, twilight = +12) ``` Parameter `unit.out` can be used to obtain the returned value expressed as time-of-day in hours, minutes, or seconds since midnight, instead of the default `datetime`. ```{r} sunrise_time(ymd("2017-03-21", tz = "EET"), tz = "EET", geocode = my.geocode) sunrise_time(ymd("2017-03-21", tz = "EET"), tz = "EET", geocode = my.geocode, unit.out = "hours") ``` Similarly, the units can also be selected for the values returned by `day_length()` and `night_length()`. ```{r} day_length(dates, geocode = my.geocode, unit.out = "days") night_length(dates, geocode = my.geocode, unit.out = "days") ``` ---- The core function is called `day_night()` and returns a data frame containing both the input values and the results of the calculations. See above for convenience functions useful in the case one needs only one of the calculated variables. In other cases it is more efficient to compute the whole data frame and later select the columns of interest. ```{r} day_night(dates[1:3], geocode = my.geocode) ``` The default for `unit.out` is `"hours"` with decimal fractions, as seen above. However other useful units like `"seconds"`, `"minutes"`, and `"days"` can be useful. ```{r} day_night(dates[1:3], geocode = my.geocode, unit.out = "days") ``` Finally it is also possible to have the timing of solar events returned as `POSIXct` time values, in which case lengths of time are still returned as fractional hours. ```{r} day_night(dates[1:3], geocode = my.geocode, unit.out = "datetime") ``` When multiple times and locations are supplied as arguments, the values returned are for all combinations of locations and times. ```{r} day_night(dates[1:3], geocode = two.geocodes) ``` ## Solar time In field research it is in many cases preferable to sample or measure, and present and plot data based on local solar time. A new class is defined in package 'photobiology', with a print method, a constructor, a conversion function and a class query function. The constructor takes as arguments a `POSIXct` object describing and instant in time and a geocode describing the geographic coordinates. ```{r} Paris.geo <- data.frame(lon = 2.352222, lat = 48.85661, address = "Paris") Paris.time <- ymd_hms("2016-09-30 06:00:00", tz = "UTC") solar_time(Paris.time, geocode = Paris.geo) solar_time(Paris.time, geocode = Paris.geo, unit.out = "datetime") ``` ```{r} my.solar.t <- solar_time(Paris.time, geocode = Paris.geo) is.solar_time(my.solar.t) is.numeric(my.solar.t) ``` ```{r} my.solar.d <- solar_time(Paris.time, geocode = Paris.geo, unit.out = "datetime") is.solar_date(my.solar.d) is.timepoint(my.solar.d) ``` ## Time of day Function `as_tod()` facilitates conversion of R's time date objects into a numeric value representing the time of day as numerical value with a decimal fraction using one of hour, minute or second as unit of expression. While solar time is based on the astronomical position of the sun, time of day is based on the time coordinates for a time zone. ```{r} times <- now(tzone = "UTC") + hours(0:6) times as_tod(times) as_tod(times, unit.out = "minutes") ``` ## Relative air mass Solar elevation determines the length of the path of the sun beam through the Earth's atmosphere. This affects the solar spectrum at ground level, specially the UVB region. Function `relative_AM()` can be used to calculate an empirical _estimate_ of this quantity from elevation angles in degrees. This function is vectorised. ```{r} relative_AM(33) ``` ```{r} relative_AM(c(80, 60, 40, 20)) ``` ## Water vapour-related calculations There are several different empirical equations in common use to estimate water vapour pressure in air over liquid water or ice. This package implements some of them as well as their inverses, which are useful to compute the dew point. Some ancillary functions help with unit conversion and computation of relative humidity. | Function | parameters | returned value | methods implemented | |:--------|:-------|:----------|:---------------------------| | water_vp_sat() | temperature, C | vapour pressure, Pa | Tetens, Magnus, Wexler, Goff-Gratch | | water_dp() | vapour pressure, Pa | temperature, C | Tetens, Magnus, Wexler | | water_fp() | vapour pressure, Pa | temperature, C | Tetens, Magnus, Wexler | | water_vp2RH() | vapour pressure, Pa; temperature, C | relative humidity, % | Tetens, Magnus, Wexler, Goff-Gratch | | water_RH2vp() | relative humidity, %; temperature, C | vapour pressure, Pa | Tetens, Magnus, Wexler, Goff-Gratch | | water_vp2mvc() | vapour pressure, Pa | mass/vol. concentration, g m$^{-3}$ | | | water_mvc2vp() | mass/vol. concentration, g m$^{-3}$ | vapour pressure, Pa | | Saturation vapour pressure in Pa at four air temperatures in C, over water, computed using Tetens equation (the default method). ```{r} water_vp_sat(c(0, 10, 20, 30)) ``` Saturation water vapour mass/volume concentration for air at 20 C, expressed in grammes per cubic meter. ```{r} water_vp2mvc(water_vp_sat(20), 20) ``` Vapour pressure for 50% relative humidity in air at a temperature of 20 C. ```{r} water_RH2vp(50, 20) ``` And the inverse computation, RH from vapour pressure in Pa and air temperature in C. ```{r} water_vp2RH(500, 40) ``` Dew point for air with a water vapour pressure of 3 kPa. ```{r} water_dp(3000) ``` ## Reference evapotranspiration Evapotranspiration is a measure of the water flux between land and atmosphere expressed as millimeters of water per unit ground area and unit time. One millimeter of evapotranspiration or precipitation is equivalent to one litre per square meter. Evapotranspiration is composed of the evaporation from the soil surface and other wet surfaces plus transpiration from plants (water evaporated inside leaves and diffusing as vapour to the outside of leaves). The condensation of dew represents a negative component. When not measured, evapotranspiration can be estimated based on energy balance and resistances to mass and heat transport. The Penman-Monteith equation is widely used. One special idealized condition is used to compute reference evapotranspiration (similar to potential evapotranspiration but with a standardized formulation by FAO that is widely used in agriculture). As implemented the computation of the energy balance is done with function `net_irradiance()` and using the value returned by this function as one argument, reference evapotranspiration is computed with function `ET_ref()`. ```{r} r_net <- net_irradiance(temperature = 20, # C sw.down.irradiance = 800, # W / m2 water.vp = 1500) # Pa r_net # W / m2 ``` ```{r} ET_ref(temperature = 20, # C water.vp = 1500, # Pa wind.speed = 4, # m / s net.irradiance = r_net ) ``` This function returns an estimate of reference evapotranspiration expressed in mm / h. Can be used with hourly means for the inputs or more frequent observations. In all cases the result is expressed as an instantaneous water flux rate expressed per hour. Function `ET_ref_day()` should be used when the input data are daily meeans or less frequent.