A satellite revolves in elliptical orbit around a planet of mass `M`. Its time period is `T` and `M` is at the centre of the path. The length of the major axis of the path is: (neglect the gravitational effect of other object in space)

A sayellite of mass m revolves in a circular orbit of radius R a round a planet of mass M. Its total energy E is :-

A satellite revolves around the earth along a circular path. If the mass of the satellite is 1000 kg and its distance from the centre of the earth is 20000 km, find the magnitude of the earth's gravitational force acting on the satellite.

A planet revolves in an elliptical orbit around the sun. The semi-major and minor axes are a and b , then the time period is given by :

A planet revolves around the sun in elliptical orbit of eccentricity 'e'. If 'T' is the time period of the planet then the time spent by the planet between the end of the minor axis and close to the sun is

Two satellites of mass M_A and M_B are revolving around a planet of mass M in radius R_A and R_B respectively. Then?

A planet revolves in an ellipticle orbit around the sun. the semimjor and semiminor axis are a and b . How time-period is related with them?

Two planets A and B are revolving in circular orbits around a fixed sun. Time period of the planet B is 2sqrt(2) times that of planet A . Find the ratio of solar constant for planet A to that of B . Neglect gravitational force between the planets.

A satellite of mass m is in an elliptical orbit around the earth of mass M(M gt gt m) the speed of the satellite at its nearest point ot the earth (perigee) is sqrt((6GM)/(5R)) where R= its closest distance to the earth it is desired to transfer this satellite into a circular orbit around the earth of radius equal its largest distance from the earth. Find the increase in its speed to be imparted at the apogee (farthest point on the elliptical orbit).