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-rw-r--r--src/solar.py126
1 files changed, 121 insertions, 5 deletions
diff --git a/src/solar.py b/src/solar.py
index a7815de..ead1653 100644
--- a/src/solar.py
+++ b/src/solar.py
@@ -203,7 +203,7 @@ def sun_geometric_mean_longitude(t):
@return :float The Sun's geometric mean longitude in radians
'''
return radians((0.0003032 * t ** 2 + 36000.76983 * t + 280.46646) % 360)
- # CANNIBALISERS and TIME TRAVELERS:
+ # CANNIBALISERS:
# The result of this function should always be positive, this
# means that after division modulo 360 but before `radians`,
# you will need to add 360 if the value is negative. This can
@@ -437,8 +437,17 @@ def solar_elevation(latitude, longitude, t = None):
return degrees(rc)
-# TODO document and demo
+
+# TODO document
def 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.
+
+ @param latitude:float The latitude in degrees northwards from the equator, negative for southwards
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return Whether there can be sunrises and sunsets where you are located
+ '''
t = julian_centuries() if t is None else t
d = degrees(solar_declination(t))
## Covert everything to the Northern hemisphere
@@ -453,6 +462,13 @@ def have_sunrise_and_sunset(latitude, t = None):
# TODO document
def is_summer(latitude, t = None):
+ '''
+ Determine whether it is summer
+
+ @param latitude:float The latitude in degrees northwards from the equator, negative for southwards
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return Whether it is summer on the hemisphere you are located on
+ '''
t = julian_centuries() if t is None else t
d = solar_declination(t)
return (d > 0) == (latitude > 0)
@@ -460,13 +476,32 @@ def is_summer(latitude, t = None):
# TODO document
def is_winter(latitude, t = None):
+ '''
+ Determine whether it is winter
+
+ @param latitude:float The latitude in degrees northwards from the equator, negative for southwards
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return Whether it is winter on the hemisphere you are located on
+ '''
t = julian_centuries() if t is None else t
d = solar_declination(t)
return not ((d > 0) == (latitude > 0))
+
# TODO document
def 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
+
+ @param delta:float Iteration step size, negative for past event, positive for future event
+ @param requested:float The value returned by `fun` for which to calculate the time point of occurrence
+ @param fun:(t:float)→float Function that calculate the data of interest
+ @param epsilon:float Error tolerance for `requested`
+ @param span:float The number of Julian centuries (0,01 for one year) to restrict the search to
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float? The calculated time point, `None` if none were found within the specified time span
+ '''
t = julian_centuries() if t is None else t
t1 = t2 = t
v1 = v0 = fun(t)
@@ -501,23 +536,53 @@ def solar_prediction(delta, requested, fun, epsilon = 0.000001, span = 0.01, t =
return None
+
# TODO document
def future_past_equinox(delta, t = None):
+ '''
+ Predict the time point of the next or previous equinox
+
+ @param delta:float Iteration step size, negative for past event, positive for future event
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float The calculated time point
+ '''
return solar_prediction(delta, 0, solar_declination, t = t)
# TODO document
def future_equinox(t = None):
+ '''
+ Predict the time point of the next equinox
+
+ @param delta:float Iteration step size, negative for past event, positive for future event
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float The calculated time point
+ '''
return future_past_equinox(0.01 / 2000, t)
# TODO document
def past_equinox(t = None):
+ '''
+ Predict the time point of the previous equinox
+
+ @param delta:float Iteration step size, negative for past event, positive for future event
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float The calculated time point
+ '''
return future_past_equinox(0.01 / -2000, t)
+
# TODO document
def future_past_solstice(delta, t = None):
+ '''
+ Predict the time point of the next or previous solstice
+
+ @param delta:float Iteration step size, negative for past event, positive for future event
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float The calculated time point
+ '''
e = 0.00001
fun = lambda t : (solar_declination(t + e) - solar_declination(t - e)) / 2
return solar_prediction(delta, 0, fun, t = t)
@@ -525,14 +590,27 @@ def future_past_solstice(delta, t = None):
# TODO document
def future_solstice(t = None):
+ '''
+ Predict the time point of the next solstice
+
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float The calculated time point
+ '''
return future_past_solstice(0.01 / 2000, t)
# TODO document
def past_solstice(t = None):
+ '''
+ Predict the time point of the previous solstice
+
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float The calculated time point
+ '''
return future_past_solstice(0.01 / -2000, t)
+
def future_past_elevation(delta, latitude, longitude, elevation, t = None):
'''
Predict the time point of the next or previous time the Sun reaches or reached a specific elevation
@@ -542,7 +620,7 @@ def future_past_elevation(delta, latitude, longitude, elevation, t = None):
@param longitude:float The longitude in degrees eastwards from Greenwich, negative for westwards
@param elevation:float The elevation of interest
@param t:float? The time in Julian Centuries, `None` for the current time
- @return :float The calculated time point, `None` if none were found within a year
+ @return :float? The calculated time point, `None` if none were found within a year
'''
return solar_prediction(delta, elevation, lambda t : solar_elevation(latitude, longitude, t), t = t)
@@ -555,7 +633,7 @@ def future_elevation(latitude, longitude, elevation, t = None):
@param longitude:float The longitude in degrees eastwards from Greenwich, negative for westwards
@param elevation:float The elevation of interest
@param t:float? The time in Julian Centuries, `None` for the current time
- @return :float The calculated time point, `None` if none were found within a year
+ @return :float? The calculated time point, `None` if none were found within a year
'''
return future_past_elevation(0.01 / 2000, latitude, longitude, elevation, t)
@@ -568,13 +646,24 @@ def past_elevation(latitude, longitude, elevation, t = None):
@param longitude:float The longitude in degrees eastwards from Greenwich, negative for westwards
@param elevation:float The elevation of interest
@param t:float? The time in Julian Centuries, `None` for the current time
- @return :float The calculated time point, `None` if none were found within a year
+ @return :float? The calculated time point, `None` if none were found within a year
'''
return future_past_elevation(0.01 / -2000, latitude, longitude, elevation, t)
+
# TODO document
def future_past_elevation_derivative(delta, latitude, longitude, elevation_derivative, t = None):
+ '''
+ Predict the time point of the next or previous time the Sun reaches or reached a specific elevation derivative
+
+ @param delta:float Iteration step size, negative for past event, positive for future event
+ @param latitude:float The latitude in degrees northwards from the equator, negative for southwards
+ @param longitude:float The longitude in degrees eastwards from Greenwich, negative for westwards
+ @param elevation_derivative:float The elevation derivative value of interest
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float? The calculated time point, `None` if none were found within a year
+ '''
fun = lambda t : solar_elevation(latitude, longitude, t)
dfun = lambda t : (fun(t + e) - fun(t - e)) / 2
return solar_prediction(delta, elevation_derivative, dfun, t = t)
@@ -582,14 +671,33 @@ def future_past_elevation_derivative(delta, latitude, longitude, elevation_deriv
# TODO document
def future_elevation_derivative(latitude, longitude, elevation_derivative, t = None):
+ '''
+ Predict the time point of the next time the Sun reaches a specific elevation derivative
+
+ @param latitude:float The latitude in degrees northwards from the equator, negative for southwards
+ @param longitude:float The longitude in degrees eastwards from Greenwich, negative for westwards
+ @param elevation_derivative:float The elevation derivative value of interest
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float? The calculated time point, `None` if none were found within a year
+ '''
return future_past_elevation_derivative(0.01 / 2000, latitude, longitude, elevation_derivative, t)
# TODO document
def past_elevation_derivative(latitude, longitude, elevation_derivative, t = None):
+ '''
+ Predict the time point of the previous time the Sun reached a specific elevation derivative
+
+ @param latitude:float The latitude in degrees northwards from the equator, negative for southwards
+ @param longitude:float The longitude in degrees eastwards from Greenwich, negative for westwards
+ @param elevation_derivative:float The elevation derivative value of interest
+ @param t:float? The time in Julian Centuries, `None` for the current time
+ @return :float? The calculated time point, `None` if none were found within a year
+ '''
return future_past_elevation_derivative(0.01 / -2000, latitude, longitude, elevation_derivative, t)
+
# TODO: This algorithm is imprecise, gives an incorrent sunrise and I do not fully know its behaviour
def sunrise_equation(latitude, longitude, t = None):
j_cent = julian_centuries() if t is None else t
@@ -612,8 +720,16 @@ def sunrise_equation(latitude, longitude, t = None):
return (julian_day_to_julian_centuries(sunset), julian_day_to_julian_centuries(sunrise))
+
# TODO document
def ptime(t):
+ '''
+ Print a time stamp in human-readable local time
+
+ This function is intended for testing
+
+ @param t The time stamp in Julian Centuries
+ '''
import datetime
print(str(datetime.datetime.fromtimestamp(int(julian_centuries_to_epoch(t)))))