A planet revolves round the sun in an elliptical orbit of minor and major axes x and y respectively . Then the time period of revolution is proportional to

Match the following columns for a planet of mass m revolving around the sun is an elliptical oribt of semi-major axis a and semi-minor axis b. T is time period of planet. {:("Column-I",,"Column-II"),((A) T^(2)propa^(3),,"(P) Kepler.s first law"),("(B) Areal velocity is constant",,"(Q) Kepler.s second law"),("(C) Orbit of planet is elliptical",,"(R) Kepler.s third law"),((D)(2pimab)/(T) = "constant",,"(S)none of the above"):}

A planet revolves around sun in an elliptical orbit of ecentricity 'e'. If 'T' is the time period of the planet then show that the time spent by the planet between the end of the minor axis and close to sun it T((1)/(4)-(e)/(2pi))

A planet revolves around sun in an elliptical orbit of ecentricity 'e'. If 'T' is the time period of the planet then show that the time spent by the planet between the end of the minor axis and close to sun it T((1)/(4)-(e)/(2pi))

A planet revolves around sun in an elliptical orbit of eccentricity .e.. If .T. is the time period of the planet then show that the time spent by the planet between the end of the minor axis and close to sun is T(1/4-e/(2pi))

A planet revolves around sun in an elliptical orbit of eccentricity .e. . If .T. is the time period of the planet then show that the time spent by the planet between the end of the minor axis and close to sun is T (1/4-(e)/(2pi))

The earth revolves round the sun in an elliptical orbit, its speed is

The earth revolves round the sun in an elliptical orbit, its speed is