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 GeoAstro Applets |
 Astronomy |
 Chaos Game |
 Java |
 Miscel- laneous |
The Analemma of the Sun, and the Eccentricity and Obliquity of the Earth.
A publication of Thomas Hebbeker about the
analemma of the Sun encouraged me to write an
interactive Java applet drawing the analemma of the Sun
depending on several parameters:
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Applet: instructions, and details:
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enter decimal values, (southern latitude negative, western longitude negative) adjust the timezone to your longitude. |
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Then hit the button "Apply
input". |
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Use the buttons to decrease
or increase the obliquity angle. |
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Use the buttons to decrease or increase the eccentricity. |
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The step size of the
buttons (obliquity, eccentricity) may be changed by the
menu items. |
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There are some more view
options. |
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Check the box to see the
current position of the Sun (if above horizon), and more
data. |
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Azimuth: minimum, current,
maximum. |
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Azimuth at max. and min.
altitude. |
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Current altitude of the
Sun, without atmospheric refraction. |
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Hit this button to open a
window showing the equation of time (diagram and table). |
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Select this item to get a
spherical projection of the sky. Drag the right side to resize the window. |
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You may use the key "h"
to increase the hour, or shift key and "h" to decrease the
hour. |
Description of my calculations:
Elliptic motion:T = orbital periodEcliptic system: L = ecliptic longitudeEquatorial coordinates: α = right ascensionHorizon system: Φ = geogr. latitude |
 equ. of time = ω + M - α |
| Kepler's equation is
solved by an iteration. Due to the rectangular coordinate system of the applet the analemma figure is distorted for high altitudes. A point at 90° of altitude is streched to a line parallel to the horizon. The equation of time (red curve) is the combined effect of eccentricity (period 1 year, blue curve), and obliquity (period half a year, green curve). |
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At present, the mean obliquity currently decreases by 0.0130° (46.8'') per century.
Near the year 12030 a minimum will be reached (22° 36' 41 '').
About the year -7530 there was a maximum inclination (24° 14' 07 '').
(Meeus: Astronomical Algorithms, Chapter 24)
According to an expression for the eccentricity by Simon et al. in 1994 (Meeus: More Mathematical Astronomy Morsels, Chapter 33).
Obliquity Applet
Orbital Eccentricity of the Earth
The analamma figure (50° N, 10° E, 11:00 UT) will change only slightly from 2013 (red, ε=23.44°, e=0.01675) to 8000 (black, ε=22.77°, e=0.01376):
Location: 50° N, 10° E,
local time: 12:00 (11:00 UT)
1. ε = 23.44°, e = 0.01675
2. ε = 0°, e = 0.01675:
3. ε = 23.44°, e = 0:
4. For ε = 23.44° and e≈0.045 (or greater) there is no intersection (knot):
5. For e = 0.016751 and ε≈13° (or less) there is no intersection (knot):
The analemma as seen on the equator:
The amplitude A of the equation of time depends on obliquity and eccentricity:
A = maximum+|minimum|
For obliquity 23.44°, eccentricity 0.016751:
maximum = 16.5 min, minimum = - 14.2 min, amplitude = 30.7 minutes.
The accuracy of my values (for 2013):
Reference: MICA (Multiyear Interactive Computer Almanac, U.S. Naval Observatory)
| mean abs. error |
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| L |
0.005° |
| RA |
0.003° |
| declination |
0.004° |
| LHA |
0.008° |
| azimuth |
0.012° |
| altitude |
0.003° |
| equ. of time |
0.015 min |
Sources and Links |
Thomas Hebbeker: Die Sonne in der Achterbahn, wie das Analemma entsteht; Sterne und Weltraum, March 2013, p. 80-87; ISSN 0039-1263 The autor determines the orbital parameters (obliquity, eccentricity) from his analemma photo. Analemma (Wikipedia) www.analemma.com Position of the Sun position of sun in sky Kepler's Equation (Wikipedia) Jörg Meyer: Die Sonnenuhr und ihre Theorie; Verlag Harri Deutsch, Frankfurt/Main 2008; ISBN 978-3-8171-1824-3 Jean Meeus: Astronomical Algorithms; Willmann-Bell, Richmond Virginia, First English Edition 1991; ISBN 0-943396-35-2 |
Updated: 2023 Oct 05