\input texinfo @c -*-texinfo-*- @c %**start of header @setfilename solar-python.info @settitle solar-python @afourpaper @documentencoding UTF-8 @documentlanguage en @finalout @c %**end of header @dircategory Astronomy @direntry * solar-python: (solar-python). Solar data calculation and prediction library for Python @end direntry @copying Copyright @copyright{} 2015 Mattias Andrée @quotation Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.3 or any later version published by the Free Software Foundation; with no Invariant Sections, with no Front-Cover Texts, and with no Back-Cover Texts. A copy of the license is included in the section entitled ``GNU Free Documentation License''. @end quotation @end copying @ifnottex @node Top @top solar-python -- Solar data calculation and prediction library for Python @insertcopying @end ifnottex @titlepage @title solar-python @subtitle Solar data calculation and prediction library for Python @author by Mattias Andrée (maandree) @page @vskip 0pt plus 1filll @insertcopying @page @end titlepage @contents @menu * Overview:: Brief overview of @command{solar-python}. * Constants:: List of constants. * Calendar functions:: List of calendar functions. * Observation functions:: List of solar data observation functions. * Prediction functions:: List of solar data prediction functions. * Miscellaneous functions:: List of miscellaneous functions. * GNU Free Documentation License:: Copying and sharing this manual. @end menu @node Overview @chapter Overview @command{solar-python} is Python 3 library that can be used to calculate information about the Sun's position and related data and predict at when time solar events occur. Import the module @code{solar_python} to use the library. Documentation is available by the command @code{help} in python. @node Constants @chapter Constants Importing @code{solar_python} makes the following constants available: @table @code @item SOLAR_APPARENT_RADIUS = 32 / 60 Approximate apparent size of the Sun in degrees. @item SOLAR_ELEVATION_PRESUNSET_POSTSUNRISE = 32 / 60 The Sun's elevation at beginning of sunset and end of sunrise, measured in degrees. @item SOLAR_ELEVATION_SUNSET_SUNRISE = -32 / 60 The Sun's elevation at (end of) sunset and (beginning of) sunrise, measured in degrees. @item SOLAR_ELEVATION_CIVIL_DUSK_DAWN = -6.0 The Sun's elevation at civil dusk and civil dawn, measured in degrees @item SOLAR_ELEVATION_NAUTICAL_DUSK_DAWN = -12.0 The Sun's elevation at nautical dusk and nautical dawn, measured in degrees @item SOLAR_ELEVATION_ASTRONOMICAL_DUSK_DAWN = -18.0 The Sun's elevation at astronomical dusk and astronomical dawn, measured in degrees @item SOLAR_ELEVATION_AMATEUR_ASTRONOMICAL_DUSK_DAWN = -15.0 The Sun's elevation at amateur astronomical dusk and amateur astronomical dawn, measured in degrees @item SOLAR_ELEVATION_RANGE_TWILIGHT = (-18.0, 0.0) The Sun's lowest and highest elevation during all periods of twilight, measured in degrees @item SOLAR_ELEVATION_RANGE_CIVIL_TWILIGHT = (-6.0, -32 / 60) The Sun's lowest and highest elevation during civil twilight, measured in degrees @item SOLAR_ELEVATION_RANGE_NAUTICAL_TWILIGHT = (-12.0, -32 / 60) The Sun's lowest and highest elevation during nautical twilight, measured in degrees @item SOLAR_ELEVATION_RANGE_ASTRONOMICAL_TWILIGHT = (-18.0, -32 / 60) The Sun's lowest and highest elevation during astronomical twilight, measured in degrees @item SOLAR_ELEVATION_RANGE_AMATEUR_ASTRONOMICAL_TWILIGHT = (-15.0, -32 / 60) The Sun's lowest and highest elevation during amateur astronomical twilight, measured in degrees @item SOLAR_ELEVATION_RANGE_GOLDEN_HOUR = (10.0, 12.0) The Sun's lowest and highest elevation during the golden hour (magic hour), measured in degrees. These elevations are approximate. @end table @node Calendar functions @chapter Calendar functions Importing @code{solar_python} makes the following calendar conversion functions available. All parameters are of the type @code{float}, and all functions return @code{float} except where noted otherwise. @table @code @item julian_day_to_epoch(t) Converts a Julian Day timestamp, @code{t}, to a POSIX time timestamp. @item epoch_to_julian_day(t) Converts a POSIX time timestamp, @code{t}, to a Julian Day timestamp @item julian_day_to_julian_centuries(t) Converts a Julian Day timestamp, @code{t}, to a Julian Centuries timestamp. @item julian_centuries_to_julian_day(t) Converts a Julian Centuries timestamp, @code{t}, to a Julian Day timestamp. @item epoch_to_julian_centuries(t) Converts a POSIX time timestamp, @code{t}, to a Julian Centuries timestamp. @item julian_centuries_to_epoch(t) Converts a Julian Centuries timestamp, @code{t}, to a POSIX time timestamp. @end table @code{solar_python} also makes the following functions available. All parameters are of the type @code{float}, and all functions return @code{float}. @table @code @item epoch() Get current POSIX time. @item julian_day() Get current Julian Day time. @item julian_centuries() Get current Julian Centuries time (100 Julian days since J2000.) @end table @node Observation functions @chapter Observation functions Importing @code{solar_python} makes the following solar data observation functions available. All parameters are of the type @code{float}, and all functions return @code{float}. All parameters named @code{t} or @code{noon} is the time in Julian Centuries. These are low-level functions. @table @code @item sun_geometric_mean_longitude(t) Calculates the Sun's geometric mean longitude. @item sun_geometric_mean_anomaly(t) Calculates the Sun's geometric mean anomaly, in radians. @item earth_orbit_eccentricity(t) Calculates the Earth's orbit eccentricity. @item sun_equation_of_centre(t) Calculates the Sun's equation of the centre --- the difference between the true anomaly and the mean anomaly --- in radians. @item sun_real_longitude(t) Calculates the Sun's real longitudinal position, in radians. @item sun_apparent_longitude(t) Calculates the Sun's apparent longitudinal position, in radians. @item mean_ecliptic_obliquity(t) Calculates the uncorrected mean ecliptic obliquity of the Sun's apparent motion without variation correction, in radians. @item corrected_mean_ecliptic_obliquity(t) Calculates the mean ecliptic obliquity of the Sun's apparent motion with variation correction, in radians. @item solar_declination(t) Calculates the Sun's declination, in radians. @item equation_of_time(t) Calculates the equation of time --- the discrepancy between apparent and mean solar time --- in degrees. @item hour_angle_from_elevation(latitude, declination, elevation) Calculates the solar hour angle, in radians, from the Sun's elevation, in radians. The Sun's elevation is gived by the parameter @code{elevation}. This functions requires two additional parameters: @table @code @item longitude The longitude in degrees eastwards from Greenwich, negative for westwards. @item declination The declination, in radians. @end table @item elevation_from_hour_angle(latitude, declination, hour_angle) Calculates the Sun's elevation, in radians, from the solar hour angle, in radians. The solar hour angle is gived by the parameter @code{hour_angle}. This functions requires two additional parameters: @table @code @item longitude The longitude in degrees eastwards from Greenwich, negative for westwards. @item declination The declination, in radians. @end table @item time_of_solar_noon(t, longitude) Calculates the time, in Julian Centuries, of the solar noon the closest to the time @code{t}. This functions requires one additional parameter: @table @code @item longitude The longitude in degrees eastwards from Greenwich, negative for westwards. @end table @item time_of_solar_elevation(t, noon, latitude, longitude, elevation) Calculates the time, in Julian Centuries, the Sun has a specified apparent elevation, expressed in radians via the parameter @code{elevation}, at a geographical position, expressed in degrees by the parameters: @table @code @item latitude The latitude in degrees northwards from the equator, negative for southwards. @item longitude The longitude in degrees eastwards from Greenwich, negative for westwards. @end table @noindent The function require two additional parameter: @table @code @item t A time, in Julian Centuries, close to the sought time. @item noon The time, in Julian Centuries, of the closest solar noon. @end table @item solar_elevation_from_time(t, latitude, longitude): Calculates the Sun's elevation, in radians, as apparent from a geographical position, expressed in degrees by the parameters: @table @code @item latitude The latitude in degrees northwards from the equator, negative for southwards. @item longitude The longitude in degrees eastwards from Greenwich, negative for westwards. @end table @end table The library also provides the high-level functions: @table @code @item solar_elevation(latitude, longitude, t = None) Calculates the Sun's elevation, in degreesm as apparent from a geographical position, expressed in degrees by the parameters: @table @code @item latitude The latitude in degrees northwards from the equator, negative for southwards. @item longitude The longitude in degrees eastwards from Greenwich, negative for westwards. @end table @noindent The function also requires to the in Julian Centuries, provided via the parameter @code{t}. If @code{t} is @code{None}, the current time is used. @item have_sunrise_and_sunset(latitude, t = None) Determine whether solar declination currently is so that there can be sunrises and sunsets. If not, you either have 24-hour daytime or 24-hour nighttime. The function requires to the in Julian Centuries, provided via the parameter @code{t}, and the latitude, provided via the parameter @code{latitude}, in degrees northwards from the equator, negative for southwards. If @code{t} is @code{None}, the current time is used. This function returns a boolean. @item is_summer(latitude, t = None) Determine whether it is summer on the hemisphere ont which you are located. The function requires to the in Julian Centuries, provided via the parameter @code{t}, and the latitude, provided via the parameter @code{latitude}, in degrees northwards from the equator, negative for southwards. If @code{t} is @code{None}, the current time is used. This function returns a boolean. @item is_winter(latitude, t = None) Determine whether it is winter on the hemisphere ont which you are located. The function requires to the in Julian Centuries, provided via the parameter @code{t}, and the latitude, provided via the parameter @code{latitude}, in degrees northwards from the equator, negative for southwards. If @code{t} is @code{None}, the current time is used. This function returns a boolean. @end table @node Prediction functions @chapter Prediction functions Importing @code{solar_python} makes the following solar data prediction functions available. All parameters are of the type @code{float}, and all functions return @code{float}. All parameters named @code{t} is the time in Julian Centuries, and the current time if set to @code{None}. Some functions require the geographical position of the observer. This latitude is provided via the parameter @code{latitude} in degrees northwards from the equator, negative for southwards. This longitude is provided via the parameter @code{longitude} in degrees eastwards from Greenwich, negative for westwards. @table @code @item solar_prediction(delta, requested, fun, epsilon = 0.000001, span = 0.01, t = None) Predict the time point of the next or previous time an arbitrary condition is meet. This function returns the calculated time in Julian Centuries, or @code{None} if the condition is not meet within the specified timespan, specified by the parameter @code{span} in Julian Centuries (@code{0.01} for one year). The function shall find the input --- one parameter in Julian Centuries --- for which the function-parameter @code{fun} returns the value of @code{requested} within an error tolerance of @code{epsilon}. The function uses the iteration step size @code{delta}. If this value is negative, a past event will be determined, and if it is positive, a future event will be predicted. @item future_past_equinox(delta, t = None) Predict the time point, in Julian Centuries, of the next or previous equinox. The function uses the iteration step size @code{delta}. If this value is negative, a past event will be determined, and if it is positive, a future event will be predicted. @item future_equinox(t = None) Predict the time point, in Julian Centuries, of the next equinox. @item past_equinox(t = None) Predict the time point, in Julian Centuries, of the previous equinox. @item future_past_solstice(delta, t = None) Predict the time point, in Julian Centuries, of the next or previous solstice. The function uses the iteration step size @code{delta}. If this value is negative, a past event will be determined, and if it is positive, a future event will be predicted. @item future_solstice(t = None) Predict the time point, in Julian Centuries, of the next solstice. @item past_solstice(t = None) Predict the time point, in Julian Centuries, of the previous solstice. @item future_past_elevation(delta, latitude, longitude, elevation, t = None) Predict the time point, in Julian Centuries, of the next or previous time the Sun reaches or reached a specific elevation, specified in degrees via the parameter @code{elevation}. @code{None} is returned if not found withing a year. The function uses the iteration step size @code{delta}. If this value is negative, a past event will be determined, and if it is positive, a future event will be predicted. @item future_elevation(latitude, longitude, elevation, t = None) Predict the time point, in Julian Centuries, of the next time the Sun reaches a specific elevation, specified in degrees via the parameter @code{elevation}. @code{None} is returned if not found withing a year. @item past_elevation(latitude, longitude, elevation, t = None) Predict the time point, in Julian Centuries, of the previous time the Sun reached a specific elevation, specified in degrees via the parameter @code{elevation}. @code{None} is returned if not found withing a year. @item future_past_elevation_derivative(delta, latitude, longitude, derivative, t = None) Predict the time point, in Julian Centuries, of the next or previous time the Sun reaches or reached a specific elevation derivative. @code{None} is returned if not found withing a year. The sought derivative is specified via the parameter @code{derivative}, expressed in degrees per Julian Century. The function uses the iteration step size @code{delta}. If this value is negative, a past event will be determined, and if it is positive, a future event will be predicted. @item future_elevation_derivative(latitude, longitude, derivative, t = None) Predict the time point, in Julian Centuries, of the next time the Sun reaches a specific elevation derivative. @code{None} is returned if not found withing a year. The sought derivative is specified via the parameter @code{derivative}, expressed in degrees per Julian Century. @item past_elevation_derivative(latitude, longitude, derivative, t = None) Predict the time point, in Julian Centuries, of the previous time the Sun reached a specific elevation derivative. @code{None} is returned if not found withing a year. The sought derivative is specified via the parameter @code{derivative}, expressed in degrees per Julian Century. @item sunrise_equation(latitude, longitude, t = None) This algorithm is imprecise, gives an incorrent sunrise. Its behaviour is not fully known. @end table @node Miscellaneous functions @chapter Miscellaneous functions Importing @code{solar_python} makes the following functions available: @table @code @item radians(deg) Convert an angle from degrees to radians. @item degrees(rad) Convert an angle from radians to degrees. @end table @node GNU Free Documentation License @appendix GNU Free Documentation License @include fdl.texinfo @bye