User:Jaxcp3/sandbox: Difference between revisions
No edit summary |
|||
Line 5: | Line 5: | ||
=Planets= |
=Planets= |
||
==Mercury== |
==Mercury== |
||
{{collapse top|title=test|bg=#CCC}} |
|||
I feel that there needs to be a table of elongations of Mercury. I have occasionally frustrated by the fact that there is no page for this data available on wikipedia, for some reason the page [[Aspects of Mercury]] was deleted some time ago. Also noteworthy is that [[Aspects of Venus]] does not have any sources listed. I suspect that the page on Mercury had a similar problem. |
I feel that there needs to be a table of elongations of Mercury. I have occasionally frustrated by the fact that there is no page for this data available on wikipedia, for some reason the page [[Aspects of Mercury]] was deleted some time ago. Also noteworthy is that [[Aspects of Venus]] does not have any sources listed. I suspect that the page on Mercury had a similar problem. |
||
Line 13: | Line 14: | ||
Because Earth and Venus both have very low eccentricities, the elongations of Venus are generally around the same angular separation. Mercury however has the largest eccentricity of the terrestrial planets. Thus the angle of elongation varies significantly between occurrences. |
Because Earth and Venus both have very low eccentricities, the elongations of Venus are generally around the same angular separation. Mercury however has the largest eccentricity of the terrestrial planets. Thus the angle of elongation varies significantly between occurrences. |
||
{{collapse bottom}} |
|||
===Western Elongations=== |
===Western Elongations=== |
||
Line 73: | Line 75: | ||
| 2015 Dec 29 || 19.7°E || -0.3 |
| 2015 Dec 29 || 19.7°E || -0.3 |
||
|} |
|} |
||
==Venus== |
==Venus== |
Revision as of 17:51, 9 August 2013
This article possibly contains original research. |
Planets
Mercury
test
|
---|
I feel that there needs to be a table of elongations of Mercury. I have occasionally frustrated by the fact that there is no page for this data available on wikipedia, for some reason the page Aspects of Mercury was deleted some time ago. Also noteworthy is that Aspects of Venus does not have any sources listed. I suspect that the page on Mercury had a similar problem. The page on Elongation (astronomy) has links to fourmilab's Mercury Chaser app as well as the Heavens Above site, which provide data relating to elongations and conjunctions. Now I'm questioning if its even worth it. Some of this info could probably be obtained from http://ssd.jpl.nasa.gov HORIZONS system. Unfortunately, they don't produce tables of elongations and conjunctions. For some reason, published lists seem to be hard to come by. Perhaps an astronomical almanac? Because Earth and Venus both have very low eccentricities, the elongations of Venus are generally around the same angular separation. Mercury however has the largest eccentricity of the terrestrial planets. Thus the angle of elongation varies significantly between occurrences. |
Western Elongations
Mercury is west of the sun so it is visible in the morning, immediately before sunrise. In the northern hemisphere at sunrise, during the months of August through October, the ecliptic is at its steepest with regards to the local horizon; this means that Mercury will rise significantly earlier than the sun, allowing easier observations. In February through April, the ecliptic is much closer to the horizon; the time between Mercury rise and sunrise will be much shorter. In the southern hemisphere, the effect is the opposite: favorable observations occur in February through April, while unfavorable elongations occur in August through October.
(source for that besides "I looked at Stellarium (computer program)")
Date | Elongation Angle | Apparent Magnitude |
---|---|---|
2012 Aug 16 | 18.7°W | +0.2 |
2012 Dec 4 | 20.6°W | -0.3 |
2013 Mar 31 | 27.8°W | +0.5 |
2013 Jul 30 | 19.6°W | +0.4 |
2013 Nov 18 | 19.5°W | -0.3 |
2014 Mar 14 | 27.6°W | +0.4 |
2014 Jul 12 | 20.9°W | +0.6 |
2014 Nov 1 | 18.7°W | -0.3 |
2015 Feb 24 | 26.7°W | +0.3 |
2015 Jun 24 | 22.5°W | +0.7 |
2015 Oct 16 | 18.1°W | -0.3 |
Eastern Elongations
Eastern elongation occurs when a body is farthest East from the sun as viewed from Earth, meaning it will set after the sun. As with western elongation, there are favorable and unfavorable observing seasons. For the northern hemisphere, August through October are favorable, February through April are unfavorable. Again, the opposite conditions apply for the southern hemisphere.
Date of Elongation | Elongation Angle | Apparent Magnitude |
---|---|---|
2012 Oct 26 | 24.1°E | +0.1 |
2013 Feb 16 | 18.1°E | -0.2 |
2013 Jun 12 | 24.3°E | +0.7 |
2013 Oct 9 | 25.3°E | +0.2 |
2014 Jan 31 | 18.4°E | -0.3 |
2014 May 25 | 22.7°E | +0.7 |
2014 Sep 21 | 26.4°E | +0.3 |
2015 Jan 14 | 18.9°E | -0.4 |
2015 May 7 | 21.2°E | +0.5 |
2015 Sep 4 | 27.1°E | +0.5 |
2015 Dec 29 | 19.7°E | -0.3 |
Venus
This is from the page on aspects of Venus as a template for Aspects of Mercury
The table contains special positions of Venus until 2021.
Greatest eastern elongation | Greatest brilliancy | Stationary, then retrograde | Inferior conjunction | Stationary, then prograde | Greatest brilliancy | Greatest western elongation | Superior conjunction |
---|---|---|---|---|---|---|---|
March 29, 2004 - 46° | May 3, 2004 | May 18, 2004 | June 8, 2004 | June 29, 2004 | July 13, 2004 | August 17, 2004 - 45.8° | March 31, 2005 |
November 3, 2005 - 47.1° | December 12, 2005 | December 23, 2005 | January 13, 2006 | February 3, 2006 | February 14, 2006 | March 25, 2006 - 46.5° | October 27, 2006 |
June 9, 2007 - 45.4° | July 14, 2007 | July 25, 2007 | August 18, 2007 | September 7, 2007 | September 23, 2007 | October 28, 2007 - 46.5° | June 9, 2008 |
January 14, 2009 - 47.1° | February 20, 2009 | March 5, 2009 | March 27, 2009 | April 15, 2009 | April 29, 2009 | June 5, 2009 - 45.9° | January 11, 2010 |
August 20, 2010 - 46° | September 27, 2010 | October 7, 2010 | October 29, 2010 | November 16, 2010 | December 2, 2010 | January 8, 2011 - 47° | August 16, 2011 |
March 27, 2012 - 46° | April 30, 2012 | May 15, 2012 | June 6, 2012 | June 27, 2012 | July 10, 2012 | August 15, 2012 - 45.8° | March 28, 2013 |
November 1, 2013 - 47.1° | December 10, 2013 | December 20, 2013 | January 11, 2014 | January 31, 2014 | February 11, 2014 | March 22, 2014 - 46.6° | October 25, 2014 |
June 6, 2015 - 45.4° | July 12, 2015 | July 23, 2015 | August 15, 2015 | September 5, 2015 | September 20, 2015 | October 26, 2015 - 46.4° | June 6, 2016 |
January 12, 2017 - 47.1° | February 18, 2017 | March 2, 2017 | March 25, 2017 | April 12, 2017 | April 26, 2017 | June 3, 2017 - 45.9° | January 9, 2018 |
August 17, 2018 - 45.9° | September 25, 2018 | October 5, 2018 | October 26, 2018 | November 24, 2018 | November 30, 2018 | January 6, 2019 - 47° | August 14, 2019 |
March 24, 2020 - 46.1° | April 28, 2020 | May 13, 2020 | June 3, 2020 | June 24, 2020 | July 8, 2020 | August 13, 2020 - 45.8° | March 26, 2021 |
Note: Greatest brilliancy is often confused with "maximum brightness". Although they are related, they are not quite the same thing. The "greatest brilliancy" is really a geometric maximum: it occurs when the apparent area of the sunlit part of Venus is greatest. Only if the luminance of Venus' apparent surface would be constant (i.e. the same at every point and at every phase) would the "greatest brilliancy" of Venus coincide with its maximum brightness. However, the reflection of sunlight on Venus more closely follows Lambert's law, which means that the maximum brightness occurs at a somewhat larger phase of Venus than its greatest brilliancy.