Calculating Altitude in Geostationary Orbit

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To calculate the altitude of a 10,000 kg satellite in geostationary orbit, the radius from the center of the Earth must be determined using Kepler's third law, which relates the orbital period to the radius. The formula T^2 = [(4π^2)/(GM_E)] r^3 can be rearranged to solve for r, but it is crucial to remember that this r is the total radius from the Earth's center, not the altitude above the surface. The altitude is found by subtracting the Earth's radius (approximately 6.37 x 10^6 m) from the calculated orbital radius. The gravitational force and centripetal force must be balanced to ensure the satellite remains in orbit. Understanding these concepts is essential for accurately determining the satellite's altitude.
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Homework Statement



A 10,000 kg satellite is rbiting the Earth in a geostationary orbit. The height of the satellite above the surface of the Earth is ?


Homework Equations



V = \omega r

Newtons gravitational force equation

Keplers third law equation

The Attempt at a Solution



I really don't understand how to set this problem up. Here is what I am thinking. We know the radius of the Earth ( 6.37 x 10 ^6 m) so all we need to find is how much above is the satellite outside of earth. That plus the radius of the Earth will give me to total radius. But what equations should I use. I don't think I know \omega nor do I know the velocity. If I use Kepler's third law equation all I get is the distance to the geosynchronous orbit. Don't know what to do.
 
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In orbit the force pulling the satelite down due to gravity is equal to the outward (centripetal force)

So for any orbital height there is a speed you need to go at to provide enough outward force. The only special thing about GSO is that the speed is exactly that needed to go around the Earth on 24hours

This is basically what Kepler's third law says - although you need the value of the constant in this case.
 
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Yes, I kind of figured that since there was no other quantity given for time, but I still don't see or understand how we would find the radius - the height of the satellite above the earth.
 
Kepler's law

T^2 = [ (4pi^2) / (GM_E) ] r^3

I would solve for r then?

but I am not sure if that gives me the distance TO the satellite.
 
Correct - or you can just use:
Force due to gravity depends on radius F = GMm/r^2
Centripetal force depends on radius F = m w^2/r
(M is mass of Earth, m is mass of satelite)


Set the forces equal to each other and find the raidus
Note that r is radius of the orbit - ie measured from the centre of the Earth, to get orbital height (above sea level) you need the raious of the Earth as well
 
WOW

I was making such a silly mistake.
I was doing what I said above - using Kepler's third law - but when I solved for r I just used r as my answer. Which was not correct at all. I needed to subtract The r I got from Kepler's law from the radius of the Earth to get my distance.

Such a silly mistake

Thanks for helping me out, much appreciated.
 

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