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  • Kepler’s First and Second Laws of planetary motion appeared in their earliest form in

  • 1609, in the book Astronomia Nova. They state that:

  • 1) Planets move in elliptical orbits about the Sun, which sits at one focus.

  • and 2) a planet’s orbital velocity varies over the course of one revolution such that a line

  • drawn between the planet and the Sun will sweep out equal area in equal time, wherever

  • in the orbit you are.

  • Kepler published his Third Law ten years later, in his 1619 book Harmonices Mundi, or The

  • Harmony of the World. By sifting through observations of how the planets move in their orbits, he

  • noticed something curious. The time it takes for a planet to orbit the Sun once (its orbital

  • period, P) is related to its average distance from the Sun (its semi-major axis, a) in a

  • very specific way:The square of the period is proportional to the semi-major axis cubed.

  • In fact, if we choose our units carefully, with the period in years (the time it takes

  • for Earth to go once around the Sun) and the semi-major axis in astronomical units, or

  • AU (the distance between the Earth and the Sun, about 150 million kilometers), the proportionality

  • becomes an exact equation: the square of the period is equal to the semi-major axis cubed.

  • Let’s try it out!

  • Earth’s semi-major axis is 1 AU (because that’s the definition of an astronomical

  • unit). Mars is farther from the Sun; it has a semi-major axis of 1.524 AU. We can use

  • Kepler’s Third Law to figure out how long it takes Mars to complete one orbit around

  • the Sun - that is, how many Earth years make up one Mars year.

  • The semi-major axis, 1.524 AU, cubed equals 3.54, and the square root of that gives us

  • Marsorbital period: 1.88 Earth years.

  • Sure enough, Mars takes 687 Earth days to orbit the Sun, which is 1.88 Earth years!

  • And this works for all of the planets in our solar system.

  • But what if we don’t want to use astronomical units and Earth years, but something more

  • conventional like kilometers? Then we have to unpack Kepler’s equation a little bit

  • more. In modern notation, it becomes: P squared equals 4 pi squared over G (the

  • gravitational constant) times M-Sun, all multiplied by a to the third power.

  • That term before the a cubed is the constant of proportionality in Kepler’s original equation.

  • M-sun is the mass of the Sun, and to be completely accurate, the equation should say M-Sun plus

  • m-planet, the mass of the Sun and planet together. But because the Sun is so much more massive

  • than even the biggest planet in our solar system, Jupiter (The mass of the sun is more

  • than a thousand times the mass of Jupiter!), the extra mass added by m-planet is tiny compared

  • to M-sun and doesn’t make much of a difference.

  • G is the gravitational constant, which might look familiar if youve ever seen Newton’s

  • Law of Gravitation, which states that the force due to gravity equals G times big M

  • times little m, all over the distance squared.

  • Actually, you can derive Kepler’s Third Law from Newton’s Law of Gravitation (although,

  • of course, Kepler didn’t know that!) by setting the force of gravity equal to the

  • centripetal force, the force the planet feels because it’s revolving around the Sun. Let’s

  • consider a circular orbit first, because that’s the simplest case. The centripetal force depends

  • on the planet’s speed, v, which for a circular orbit is constant:

  • F centripetal equals m v squared over r.

  • Setting these two forces equal to each other gives us a relationship that simplifies to

  • v equals the square root of G times M over r:

  • Now, since were considering a circular orbit at the moment, we also know that there’s

  • a relationship between the speed, v, and the orbital period, P. The planet has to go around

  • the whole circumference of the orbit (2pi r) in the time P, so the speed must be equal

  • to 2 pi r over P:

  • And if we substitute that into our force equation from before, and use the semi-major axis,

  • a, as our distance from the Sun (now were back to elliptical orbits), we have

  • 2 pi a over P equals the square root of G times M over a:

  • After some rearranging, weve gotten back to Kepler’s Third Law! That is,

  • P squared equals 4 pi squared over G times M-Sun,

  • all multiplied by a cubed.

  • This expression is especially informative because it relates two values that you can

  • measure with a telescope - distance to the Sun and orbital period - to the mass of the

  • Sun, and that’s how we know how heavy the Sun is! Even better, it works for all kinds

  • of orbiting systems. You can find the mass of the Earth, for example, by rewriting the

  • equation using the distance and orbital period of the Moon:

  • The Moon’s orbital period, P-Moon, is 27.3 days, or 2,358,720 seconds and the semi-major

  • axis of the Moon’s orbit, aMoon, is 384,400,000 m.

  • G, as usual, is 6.67 × 10^-11 meters cubed per kilogram per second squared.

  • Solving the equation using these parameters

  • yields an estimate for the mass of the Earth of

  • 6 times ten to the 24 kilograms.

  • Any planet with a moon can easily beweighedthis way,

  • and it’s all thanks to Kepler’s Third Law!

Kepler’s First and Second Laws of planetary motion appeared in their earliest form in

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開普勒第三定律 (Kepler's Third Law of Motion (Astronomy))

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    林宜悉 發佈於 2021 年 01 月 14 日
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