def test_calc_time(): import pytz import math # validation from USNO solar position calculator online epoch = datetime.datetime(1970, 1, 1) epoch_dt = pytz.utc.localize(epoch) loc = tus loc.pressure = 0 actual_time = pytz.timezone(loc.tz).localize( datetime.datetime(2014, 10, 10, 8, 30)) lb = pytz.timezone(loc.tz).localize(datetime.datetime(2014, 10, 10, tol)) ub = pytz.timezone(loc.tz).localize(datetime.datetime(2014, 10, 10, 10)) alt = solarposition.calc_time(lb, ub, loc.latitude, loc.longitude, 'alt', math.radians(24.7)) az = solarposition.calc_time(lb, ub, loc.latitude, loc.longitude, 'az', math.radians(116.3)) actual_timestamp = (actual_time - epoch_dt).total_seconds() assert_allclose( (alt.replace(second=0, microsecond=0) - epoch_dt).total_seconds(), actual_timestamp) assert_allclose( (az.replace(second=0, microsecond=0) - epoch_dt).total_seconds(), actual_timestamp)
def test_calc_time(): import pytz import math # validation from USNO solar position calculator online epoch = datetime.datetime(1970,1,1) epoch_dt = pytz.utc.localize(epoch) loc = tus loc.pressure = 0 actual_time = pytz.timezone(loc.tz).localize(datetime.datetime(2014, 10, 10, 8, 30)) lb = pytz.timezone(loc.tz).localize(datetime.datetime(2014, 10, 10, 6)) ub = pytz.timezone(loc.tz).localize(datetime.datetime(2014, 10, 10, 10)) alt = solarposition.calc_time(lb, ub, loc, 'alt', math.radians(24.7)) az = solarposition.calc_time(lb, ub, loc, 'az', math.radians(116.3)) actual_timestamp = (actual_time - epoch_dt).total_seconds() assert_almost_equals((alt.replace(second=0, microsecond=0) - epoch_dt).total_seconds(), actual_timestamp) assert_almost_equals((az.replace(second=0, microsecond=0) - epoch_dt).total_seconds(), actual_timestamp)
def time_calc_time(self): # datetime.datetime(2020, 9, 14, 13, 24, 13, 861913, tzinfo=<UTC>) solarposition.calc_time( self.start, self.end, self.lat, self.lon, self.attribute, self.value )