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Today's sunrise/sunset calculation for 39.040759 °N, 77.04876 °W.Note: I am not using the appropriate number of significant figures to calculate sunrise, sunset, and solar noon. While it may appear that my calculations are accurate to one second, they actually have a precision of closer to 3 minutes (mostly due to approximation). Also, this calculation does not take into account the effect of air temperature, altitude, etc. Together, these may affect the time by 5 minutes or more. Find today's Julian date (days since Jan 1, 2000 + 2451545): Julian date: 2460427Now, calculate Jtransit at longitude 77.04876, start with n:
n* = (Jdate - 2451545 - 0.0009) - (lw/360)
n = round(n*) n* = (2460427 - 2451545 - 0.0009) - (77.04876/360) = 8881.7850756667 n = round(8881.7850756667) = 8882 Now J*:
J* = 2451545 + 0.0009 + (lw/360) + n
J* = 2451545 + 0.0009 + (77.04876/360) + 8882 = 2460427.2149243 Using J*, calculate M (mean anomaly) and then use that to calculate C and λ:
M = [357.5291 + 0.98560028 * (J* - 2451545)] mod 360
M = [357.5291 + 0.98560028 * (2460427.2149243 - 2451545)] mod 360 = 9111.8426164429 mod 360 = 111.84261644293 We need to calculate the equation of center, C:
C = (1.9148 * sin(M)) + (0.0200 * sin(2 * M)) + (0.0003 * sin(3 * M))
C = 1.9148 * sin(111.84261644293) + 0.0200 * sin(2 * 111.84261644293) + 0.0003 * sin(3 * 111.84261644293) = 1.7633970626169 We need λ which is the ecliptical longitude of the sun:
λ = (M + 102.9372 + C + 180) mod 360
λ = (111.84261644293 + 102.9372 + 1.7633970626169 + 180) mod 360 = 396.54321350555 mod 360 = 36.54321350555 Finally, calculate Jtransit:
Jtransit = J* + (0.0053 * sin(M)) - (0.0069 * sin(2 * λ))
Jtransit = 2460427.2149243 + (0.0053 * sin(111.84261644293)) - (0.0069 * sin(2 * 36.54321350555)) = 2460427.2132423 Now, to get an even more accurate number, recursively recalculate M using Jtransit until it stops changing. Notice how close the approximation was.
I1: M = 111.84095863458, C = 1.7634184883756, λ = 36.541577122951, Jtransit = 2460427.2132425
I2: M = 111.84095880439, C = 1.763418486181, λ = 36.54157729057, Jtransit = 2460427.2132425 I3: M = 111.84095880439, C = 1.763418486181, λ = 36.54157729057, Jtransit = 2460427.2132425 Ok, translate this into something we understand. i.e. When is Solar Noon?
Jtransit =
2460427.2132425 = 04/26/2024 at 13:07:04 -0500
Alrighty, now calculate how long the sun is in the sky at latitude 39.040759: Now we need to calculate δ which is the declination of the sun:
δ = arcsin( sin(λ) * sin(23.45) )
δ = arcsin(sin(36.54157729057) * sin(23.45)) = 13.706064910861 Now we can go about calculating H (Hour angle):
H = arccos( [sin(-0.83) - sin(ln) * sin(δ)] / [cos(ln) * cos(δ)] )
H = arccos((sin(-0.83) - sin(39.040759) * sin(13.706064910861))/(cos(39.040759) * cos(13.706064910861))) = 102.53167810813 Just as above, calculate J*, but this time using hour-angle:
J** = 2451545 + 0.0009 + ((H + lw)/360) + n
J** = 2451545 + 0.0009 + ((102.53167810813 + 77.04876)/360) + 8882 = 2460427.4997346 We can use M from above because it really doesn't change that much over the course of a day, calculate Jset in the same way:
Jset = J** + (0.0053 * sin(M)) - (0.0069 * sin(2 * λ))
Jset = 2460427.4997346 + (0.0053 * sin(111.84095880439)) - (0.0069 * sin(2 * 36.54157729057)) = 2460427.4980527 Now I'm going to cheat and calculate Jrise:
Jrise = Jtransit - (Jset - Jtransit)
Jrise = 2460427.2132425 - (2460427.4980527 - 2460427.2132425) = 2460426.9284323 Using the same idea, figure out when sunrise and sunset are:
Jrise =
2460426.9284323 = 04/26/2024 at 06:16:56 -0500
Jset = 2460427.4980527 = 04/26/2024 at 19:57:11 -0500 A couple anomalies occur. At high latitudes, you will sometimes get H = 0. This means that either the sun does not rise (in the winter) or the sun does not set (in the summer) on that day. |