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8: Planetary Motions

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    6839

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    In this chapter, I do not attempt to calculate planetary ephemerides, which will come in a later chapter. Rather, I discuss in an idealistic and qualitative manner how it is that a planet sometimes moves in one direction and sometimes in another. That the treatment in this chapter is both idealistic and qualitative by no means implies that it will be devoid of Equations or of quantitative results, or that the matter discussed in this chapter will have no real practical or observational value.

    • 8.1: Introduction to Planetary Motions
      The word “planet” means “wanderer” (πλάνητες αστέρες − wandering stars); in contrast to the “fixed stars”, the planets wander around on the celestial sphere, sometimes moving from east to west and sometimes from west to east – and of course there are “stationary points” at the instant when their motions change from one direction to the other.
    • 8.2: Opposition, Conjunction and Quadrature
      This page classifies planets into inferior (Mercury and Venus) and superior (Mars and others) based on their distance from the Sun. It explains inferior and superior conjunctions, orbital characteristics, and greatest elongations. The page also discusses the relationship between orbital distances and angular separations from the Sun, using Venus and Mercury as examples, and includes figures illustrating the orbits of Earth alongside these planets, emphasizing important observational points.
    • 8.3: Sidereal and Synodic Periods
      This page examines the orbits of Earth and inferior planets, focusing on angular speeds and periods. It defines sidereal and synodic periods and explains the relationship between them with formulas. Mars has the longest synodic period at 780 days, while Mercury has the shortest at 116 days. The content highlights the variation of synodic periods in relation to sidereal years for various planets.
    • 8.4: Direct and Retrograde Motion, and Stationary Points
      This page covers planetary motion in relation to Earth, explaining prograde and retrograde movement, and how angular speeds vary with reference frames. It details equations for calculating apparent motions of planets at opposition and conjunction, clarifying stationary points. The heliocentric distances of planets and the proper motion of asteroids are analyzed, introducing formulas for estimating orbital radius based on angular distance and proper motion.

    Thumbnail: This montage, assembled from individual Galileo and Voyager images, shows a “family portrait” of Jupiter (with its giant red spot) and its four large moons. From top to bottom, we see Io, Europa, Ganymede, and Callisto. The colors are exaggerated by image processing to emphasize contrasts. (credit: modification of work by NASA).​​​

    This page titled 8: Planetary Motions is shared under a CC BY-NC 4.0 license and was authored, remixed, and/or curated by Jeremy Tatum via source content that was edited to the style and standards of the LibreTexts platform.