basics
Satellites orbit around the earth. Depending on the application, these orbits can be circular or elliptical. Satellites in circular orbits always keep the same distance to the earth’s surface following a simple law:
The attractive force Fg of the earth due to gravity equals mg (R/r) 2 .
The centrifugal force Fc trying to pull the satellite away equals mrω2 .The variables have the following meaning: m is the mass of the satellite; R is the radius of earth with R = 6,370 km; r is the distance of the satellite to the centre of the earth; g is the acceleration of gravity with g = 9.81 m/s2; ω is the angular velocity = 2πf, f is the frequency of the rotation. To keep the satellite in a stable circular orbit, the following equation must hold: Fg = Fc, i.e., both forces must be equal. Solving the equation for the distance r of the satellite to the centre of the earth results in the following equation:
The distance r = (gR2/(2πf)2)1/3 .From the above equation it can be concluded that the distance of a satellite to the earth’s surface depends on its rotation frequency. e
The attractive force Fg of the earth due to gravity equals mg (R/r) 2 .
The centrifugal force Fc trying to pull the satellite away equals mrω2 .The variables have the following meaning: m is the mass of the satellite; R is the radius of earth with R = 6,370 km; r is the distance of the satellite to the centre of the earth; g is the acceleration of gravity with g = 9.81 m/s2; ω is the angular velocity = 2πf, f is the frequency of the rotation. To keep the satellite in a stable circular orbit, the following equation must hold: Fg = Fc, i.e., both forces must be equal. Solving the equation for the distance r of the satellite to the centre of the earth results in the following equation:
The distance r = (gR2/(2πf)2)1/3 .From the above equation it can be concluded that the distance of a satellite to the earth’s surface depends on its rotation frequency. e