MINOR EDIT: I say below that JPL's Horizons library is not open source. Actually, it is, and it's available here: http://naif.jpl.nasa.gov/naif/tutorials.html
At 2013-01-01 00:00:00 UTC at 0 degrees north latitude, 0 degrees east latitude, sea level elevation, what is the J2000 epoch right ascension and declination of the moon?
Sadly, different libraries give slightly different answers. Converted to degrees, the summarized results (RA first):
Stellarium: 141.9408333000, 9.8899166666 [precision: .0004166640, .0000277777] Pyephem: 142.1278749990, 9.8274722221 [precision .0000416655, .0000277777] Libnova: 141.320712606865, 9.76909442356909 [precision unknown] Horizons: 141.9455833320, 9.8878888888 [precision: .0000416655, .0000277777]
My question: why? Notes:
I realize these differences are small, but:
I use pyephem and libnova to calculate sun/moon rise/set, and these times can be very sensitive to position at higher latitudes (eg, midnight sun).
I can understand JPL's Horizons library not being open source, but the other three are. Shouldn't someone work out the differences in these libraries and merge them? This is my main complaint. Do the stellarium/pyephem/libnova library authors have a fundamental difference in how to make these calculations, or do they just need to merge their code?
I also realize there might be other reasons the calculations are different, and would appreciate any help in rectifying these possible errors:
Pyephem and Libnova may be using the epoch of the date instead of J2000
The moon is close enough that observer location can affect its RA/DEC (parallax effect).
I'm using Perl's Astro::Nova and Python's pyephem, not the original C implementations of these libraries. However, if these differences are caused by using Perl/Python, that is important in my opinion.
My code (w/ raw results):
- First, Perl and Astro::Nova:
#!/bin/perl # RA/DEC of moon at 0N 0E at 0000 UTC 01 Jan 2013 use Astro::Nova; # 1356998400 == 01 Jan 2013 0000 UTC $jd = Astro::Nova::get_julian_from_timet(1356998400); $coords = Astro::Nova::get_lunar_equ_coords($jd); print join(",",($coords->get_ra(), $coords->get_dec())),"\n"; RESULT: 141.320712606865,9.76909442356909
- Second, Python and pyephem:
#!/usr/local/bin/python # RA/DEC of moon at 0N 0E at 0000 UTC 01 Jan 2013 import ephem; e = ephem.Observer(); e.date = '2013/01/01 00:00:00'; moon = ephem.Moon(); moon.compute(e); print moon.ra, moon.dec RESULT: 9:28:30.69 9:49:38.9
- The stellarium result (snapshot):
- The JPL Horizons result (snapshot):
[JPL Horizons requires POST data (not really, but pretend), so I couldn't post a URL].
I haven't linked them (lazy), but I believe there are many unanswered questions on stackoverflow that effectively reduce to this question (inconsistency of precision astronomical libraries), including some of my own questions.
I'm playing w this stuff at: https://github.com/barrycarter/bcapps/tree/master/ASTRO