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I'm going to need someone to explain this to me (1 Viewer)
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Jaydels
Member
this is what i wrote:
Orbital velocity is the instantaneous speed in the direction indicated by an arrow drawn as a tangent to the point of interest on the orbital path.
A centripetal force is required to keep an object moving in a circular path. For a planet revolving around the sun in a circular orbit or radius r, the centripetal force is provided by the gravitational attraction between the planet and the sun. If the mass of the planet (satellite) is m and the mass of the sun (central body)is M then:
Fc= mv^2/r
= GmM/r^2
v^2=GM/r
=(2pi r/T)^2
r^3/T^2=GM/4pi^2 (Kepler's Law of Periods)
For any two bodies orbiting the same object, the ratio r^3:T^2 always equals the same fixed value.
The square of a planet's orbital period is proportional to the cube of the mean distance of the planet from the sun.
Feel free to correct me anyone..........
Orbital velocity is the instantaneous speed in the direction indicated by an arrow drawn as a tangent to the point of interest on the orbital path.
A centripetal force is required to keep an object moving in a circular path. For a planet revolving around the sun in a circular orbit or radius r, the centripetal force is provided by the gravitational attraction between the planet and the sun. If the mass of the planet (satellite) is m and the mass of the sun (central body)is M then:
Fc= mv^2/r
= GmM/r^2
v^2=GM/r
=(2pi r/T)^2
r^3/T^2=GM/4pi^2 (Kepler's Law of Periods)
For any two bodies orbiting the same object, the ratio r^3:T^2 always equals the same fixed value.
The square of a planet's orbital period is proportional to the cube of the mean distance of the planet from the sun.
Feel free to correct me anyone..........