Apparent retrograde motion

From Wikipedia, the free encyclopedia
This article is about the apparent motion of planets as observed from a particular vantage point. For retrograde motions of celestial bodies relative to a gravitationally central object, see Retrograde and prograde motion.
As Earth (blue) passes a superior planet such as Mars (red), the superior planet will temporarily appear to reverse its motion across the sky.
Schematic animation of Mars retrograde. As Earth (E) passes a superior planet such as Mars (M), the superior planet (M') will temporarily appear to reverse its motion across the sky.

Apparent retrograde motion is the apparent motion of a planet in a direction opposite to that of other bodies within its system, as observed from a particular vantage point. Direct motion or prograde motion is motion in the same direction as other bodies.

While the terms direct and prograde are equivalent in this context, the former is the traditional term in astronomy. The earliest recorded use of prograde was in the early 18th century, although the term is now less common.[1]

Etymology[]

The term retrograde is from the Latin word retrogradus – "backward-step", the affix retro- meaning "backwards" and gradus "step". Retrograde is most commonly an adjective used to describe the path of a planet as it travels through the night sky, with respect to the zodiac, stars, and other bodies of the celestial canopy. In this context, the term refers to planets, as they appear from Earth, stopping briefly and reversing direction at certain times, though in reality, of course, we now understand that they perpetually orbit in the same uniform direction.[2]

Although planets can sometimes be mistaken for stars as one observes the night sky, the planets actually change position from night to night in relation to the stars. Retrograde (backward) and prograde (forward) are observed as though the stars revolve around the Earth. Ancient Greek astronomer Ptolemy in 150 AD believed that the Earth was the center of the Solar System and therefore used the terms retrograde and prograde to describe the movement of the planets in relation to the stars. Although it is known today that the planets revolve around the sun, the same terms continue to be used in order to describe the movement of the planets in relation to the stars as they are observed from Earth. Like the sun, the planets appear to rise in the East and set in the West. When a planet travels eastward in relation to the stars, it is called prograde. When the planet travels westward in relation to the stars (opposite path) it is called retrograde.[3]

Apparent motion[]


T1, T2, ..., T5 – positions of Earth
P1, P2, ..., P5 – positions of a planet
A1, A2, ..., A5 – projection to celestial sphere

From Earth[]

When standing on the Earth looking up at the sky, it would appear that the Moon travels from east to west, just as the Sun and the stars do. Day after day however, the Moon appears to move to the east with respect to the stars. In fact, the Moon orbits the Earth from west to east, as do the vast majority of manmade satellites such as the International Space Station. The apparent westward motion of the Moon from the Earth's surface is actually an artifact of its being in a supersynchronous orbit. This means that the Earth completes one sidereal rotation before the Moon is able to complete one orbit. As a result, it looks like the Moon is travelling in the opposite direction, otherwise known as apparent retrograde motion. This phenomenon also occurs on Mars, which has two natural satellites, Phobos and Deimos. Both moons orbit Mars in an eastward (prograde) direction; however, Deimos has an orbital period of 1.23 Martian sidereal days, making it supersynchronous, whereas Phobos has an orbital period of 0.31 Martian sidereal days, making it subsynchronous. Consequently, although both moons are traveling in an eastward (prograde) direction, they appear to be traveling in opposite directions when viewed from the surface of Mars due to their orbital periods in relation to the rotational period of the planet.

Apparent path of Mars in 2009–2010 relative to the constellation Cancer, showing its "opposition loop" or "retrograde loop"
The asteroid 514107 Kaʻepaokaʻawela has a retrograde orbit. Its apparent retrograde motion occurs at superior conjunction with the sun, as shown in this example in 2018.

All other planetary bodies in the Solar System also appear to periodically switch direction as they cross Earth's sky. Though all stars and planets appear to move from east to west on a nightly basis in response to the rotation of Earth, the outer planets generally drift slowly eastward relative to the stars. Asteroids and Kuiper Belt objects (including Pluto) exhibit apparent retrogradation. This motion is normal for the planets, and so is considered direct motion. However, since Earth completes its orbit in a shorter period of time than the planets outside its orbit, it periodically overtakes them, like a faster car on a multi-lane highway. When this occurs, the planet being passed will first appear to stop its eastward drift, and then drift back toward the west. Then, as Earth swings past the planet in its orbit, it appears to resume its normal motion west to east.[4] Inner planets Venus and Mercury appear to move in retrograde in a similar mechanism, but as they can never be in opposition to the Sun as seen from Earth, their retrograde cycles are tied to their inferior conjunctions with the Sun. They are unobservable in the Sun's glare and in their "new" phase, with mostly their dark sides toward Earth; they occur in the transition from evening star to morning star.

The more distant planets retrograde more frequently, as they do not move as much in their orbits while Earth completes an orbit itself. The retrogradation of a hypothetical extremely distant (and nearly non-moving) planet would take place during a half-year, with the planet's apparent yearly motion being reduced to a parallax ellipse.

The center of the retrograde motion occurs at the planet's opposition which is when it is exactly opposite the Sun.  This is halfway or 6 months around the ecliptic from the Sun.  The planet's height in the sky is opposite that of the Sun's; if it occurs around the Winter Solstice when the Sun passes lowest in the sky, the retrograde will pass high in the sky at midnight, and conversely it will pass low in the sky when retrograde occurs around the Summer Solstice.  Since the planet's opposition retrograde motion is when the Earth passes closest, the planet appears at its brightest for the year.

The period between the center of such retrogradations is the synodic period of the planet.

Planetary retrograde constants
Planet Synodic period (days) Synodic period (mean months) Days in retrogradation
Mercury 116 3.8 ≈ 21
Venus 584 19.2 41
Mars 780 25.6 72
Jupiter 399 13.1 121
Saturn 378 12.4 138
Uranus 370 12.15 151
Neptune 367 12.07 158
Hypothetical far-out planet 365.25 12 182.625
Apparent retrograde motion of Mars in 2003 as seen from Earth

This apparent retrogradation puzzled ancient astronomers, and was one reason they named these bodies 'planets' in the first place: 'Planet' comes from the Greek word for 'wanderer'. In the geocentric model of the Solar System proposed by Apollonius in the third century BCE, retrograde motion was explained by having the planets travel in deferents and epicycles.[4] It was not understood to be an illusion until the time of Copernicus, although the Greek astronomer Aristarchus in 240 BCE proposed a heliocentric model for the Solar System.

Galileo's drawings show that he first observed Neptune on December 28, 1612, and again on January 27, 1613. On both occasions, Galileo mistook Neptune for a fixed star when it appeared very close—in conjunction—to Jupiter in the night sky, hence, he is not credited with Neptune's discovery. During the period of his first observation in December 1612, Neptune was stationary in the sky because it had just turned retrograde that very day. Since Neptune was only beginning its yearly retrograde cycle, the motion of the planet was far too slight to be detected with Galileo's small telescope.

Retrograde dates[5] in 2018
Planet stationary (retrograde) opposition or inferior conjunction stationary (direct)
Mercury Nov 17 Nov 27 Dec 6
Venus Oct 5 Oct 26 Nov 14
Mars Jun 28 Jul 27 Aug 28
Jupiter Mar 9 May 9 Jul 11
Saturn Apr 18 Jun 27 Sep 6
Uranus Aug 7 Oct 24 Jan 6
Neptune Jun 19 Sept 7 Nov 25
Retrograde dates[6][7][8] in 2019
Planet stationary (retrograde) opposition or inferior conjunction stationary (direct)
Mercury Mar 5 Mar 15 Mar 28
Jul 7 Jul 19 Aug 1
Nov 1 Nov 11 Nov 21
Venus ----- ----- -----
Mars ----- ----- -----
Jupiter Apr 10 Jun 10 Aug 11
Saturn Apr 29 Jul 9 Sep 18
Uranus Aug 11 Oct 28 Jan 11
Neptune Jun 21 Sept 10 Nov 27
Retrograde dates[9] in 2020
Planet stationary (retrograde) opposition or inferior conjunction stationary (direct)
Mercury Feb 16 Feb 26 Mar 9
Jun 18 Jun 30 Jul 12
Oct 14 Oct 24 Nov 3
Venus May 13 Jun 3 Jun 25
Mars Sep 10 Oct 13 Nov 14
Jupiter May 15 Jul 13 Sep 13
Saturn May 11 Jul 21 Sep 29
Uranus Aug 16 Oct 31 Jan 15
Neptune Jun 24 Sept 11 Nov 29

From Mercury[]

From any point on the daytime surface of Mercury when the planet is near perihelion (closest approach to the Sun), the Sun undergoes apparent retrograde motion. This occurs because, from approximately four Earth days before perihelion until approximately four Earth days after it, Mercury's angular orbital speed exceeds its angular rotational velocity.[10] Mercury's elliptical orbit is farther from circular than that of any other planet in the Solar System, resulting in a substantially higher orbital speed near perihelion. As a result, at specific points on Mercury's surface an observer would be able to see the Sun rise part way, then reverse and set before rising again, all within the same Mercurian day.

See also[]

References[]

  1. ^ "Prograde, adj". OED Online version. Oxford University Press. 2012. {{cite web}}: Missing or empty |url= (help)
  2. ^ Carrol, Bradley and Ostlie, Dale, An Introduction to Modern Astrophysics, Second Edition, Addison-Wesley, San Francisco, 2007. pp. 3
  3. ^ "Retrograde | Define Retrograde at Dictionary.com". Dictionary.reference.com. Retrieved 2012-08-17.
  4. ^ a b Carrol, Bradley and Ostlie, Dale, An Introduction to Modern Astrophysics, Second Edition, Addison-Wesley, San Francisco, 2007. pp. 4
  5. ^ Ottewell, Guy. "Astronomical Calendar 2018, Timetable of events". Retrieved 2018-09-26.
  6. ^ Victor, Robert (August 2018). "School-Year Preview of Planetary Events, August 2018-June 2019". Archived from the original on 2019-08-22. Retrieved 2018-10-05.
  7. ^ "Topocentric Configuration of Major Solar System Bodies". Retrieved 2018-10-05.
  8. ^ Edgar, James S. (editor). Observer's Handbook 2019. The Royal Astronomical Society of Canada. ISBN 9-781927-879153.
  9. ^ "Planetary Ephemeris Data". Retrieved 2018-12-08.
  10. ^ Strom, Robert G.; Sprague, Ann L. (2003). Exploring Mercury: the iron planet. Springer. ISBN 1-85233-731-1.

External links[]

Retrieved from ""