Express your answer in terms of,,,,, and, the magnitude of the acceleration due to gravity
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- You may use the following constants
- Give the orbital radius in meters to three significant digits.
Express your answer in terms of  ,  ,  , and  .
 Express the kinetic energy  in terms of the potential energy  .
Find the orbital period  .
Express your answer in terms of , , , and  .
Find an expression for the square of the orbital period.
Express your answer in terms of , , , and .
Find  , the magnitude of the angular momentum of the satellite with respect to the center of the planet.
Express your answer in terms of , , , and .
The quantities  , , , and all represent physical quantities characterizing the orbit that depend on radius . Indicate the exponent (power) of the radial dependence of the absolute value of each.
Express your answer as a comma-separated list of exponents corresponding to , , , and , in that order. For example, -1,-1/2,-0.5,-3/2 would mean  ,  , and so forth.
Geosynchronous Satellite  A satellite that goes around the earth once every 24 hours is called a geosynchronous satellite. If a geosynchronous satellite is in an equatorial orbit, its position appears stationary with respect to a ground station, and it is known as a geostationary satellite.
Give the orbital radius in meters to three significant digits.
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A Satellite with Drag This problem concerns the properties of circular orbits for a satellite of mass In doing this problem, you are to assume that the planet has an atmosphere that causes a small drag due to air resistance. "Small" means that there is little change during each orbit so that the orbit remains nearly circular, but the radius can change slowly with time. The following questions will ask about the net effects of drag and gravity on the satellite's motion, under the assumption that the satellite's orbit stays nearly circular. Use if necessary for the universal gravitational constant.
Post-Collision Orbit A small asteroid is moving in a circular orbit of radius Since the asteroid does not reach escape velocity, it must remain in a bound orbit around the sun, which will be an ellipse. Take the following steps to find As in most orbit problems, the most fundamental principles involved are energy and angular momentum conservation.
 ,  , and  are given initial conditions, and the values of , , and are known constants. The total energy and angular momentum may be expressed entirely in terms of these known, fixed quantities. This means that we should be able to express any of the fixed quantities related to the new orbit in terms of  , , and known constants, instead of using the initial conditions.
Now focus on the new orbit of the asteroid. The final goal is to find
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Assume that the mass of the asteroid is 
and 
, the aphelion and perihelion distance of the asteroid after the collision. (The aphelion is the point in the orbit farthest from the sun, and the perihelion is the point in the orbit closest to the sun.) 
and 
be the orbital speeds at aphelion and perihelion respectively.