If the period of revolution of an artificial satellite just above the earth be T second and the density of earth be `rho , kg//m^(3)` then
(G =`6.67 xx 10^(-11) m^(3)//kg . "second"^(2)`)

If the period of revolution of an artificial satellite just above the earth's surface is T and the density of earth is p, then pT^(2) is

If the period of revolution of an artificial satellite above the earth's surface be T and the density of earth be p, then prove that p T^(2) is a universal constant. Also calculate the value of this constant. Given G= 6.67xx10^(-11)m^(3) kg^(-1)s^(-2)

The time period 'T' of the artificial satellite of earth depends on the average density rho of the earth as

If T is the period of a satellite revolving very close to the surface of the earth and if rho is the density of the earth, then

Calculate the period of revolution of a satellite orbiting above the surface of the Earth at a distance equal to 9 times the radius of the Earth.

The time period of revolution of moon around the earth is 28 days and radius of its orbit is 4xx10^(5) km. If G=6.67xx10^(-11) Nm^(2)//kg^(2) then find the mass of the earth.

A small satellite revolves around a planet in an orbit just above planet's surface. Taking the mean density of the planet 8000 kg m^(-3) and G = 6.67 xx 10^(-11) N //kg^(-2) , find the time period of the satellite.

Calculate mass of earth taking it to ne a sphere of radius 6400 km. given g=9.8 m//s^(2) and G=6.67xx10^(-11)N m^(2)kg^(-2)

Determine the gravitational potential on the surface of earth, given that radius of the earth is 6.4 xx 10^(6) m : its mean density is 5.5 xx 10^(3)kg m^(-3) , G = 6.67 xx 10^(-11) Nm^(2) kg^(-2) .

Estimate the mass of the sun, assuning the orbit of Earth round the sun to be a circule. The disatnce between the sun and the Earth is 1.49 xx 10^(11) m , and G = 6.67 xx 10^(-11) Nm^(2) kg^(-2) .