Two planets at mean distance `d_(1)` and `d_(2)` from the sun and their frequencies are n and n respectively then

Two planets are at distance R_1 and R_2 from the Sun. Their periods are T_1 and T_2 then (T_1/T_2)^2 is equal to

The mean distance of two planets A and B from the sun is 2 and 4 times the distance of the Earth from the sun, respectively. Find the ratio of the time taken by the two planets to make one revolution around the sun.

A planet is at an average distance d from the sun and its average surface temeperature is T. Assume that the planet receives energy only from the sun and loses energy only through radiation from the surface. Neglect atmospheric effects. If Tpropd^(-n) , the value of n is

A planet moves aruond the sun in an elliptical orbit such that its kinetic energy is K_(1) and K_(2) when it is nearest to the sun and farthest from the sun respectively. The smallest distance and the largest distance between the planet and the sun are r_(1) and r_(2) respectively.

Two planets A and B are at distances of 10^(9) m and 10^(11) m from the sun respectively. Calculate the ration of speeds of the two planets.

If r denotes the mean distance of a planet from the sun and T is the time period of planet, then

If two planets of radii R_(1) and R_(2) have densities d_(1) and d_(2) , then the ratio of their respective acceleration due to gravity is

Two planets have radii r_(1) and r_(2) and densities d_(1) and d_(2) respectively. Then the ratio of acceleration due to gravity on them is

A planet of mass m moves along an ellipse around the sun so that its maximum and minimum distance from the sun are equal to r_(1) and r_(2) respectively. Find the angular momentum of this planet relative to the centre of the sun. mass of the sun is M .