A : Kepler's law cannot be used for asteroids and comets .
R: Asteroids and comets do not revolve around sun under its gravitational force .

A : During orbital motion of planet around the sun work done by the centripetal force is not zero at all points on the orbit . R : Planet is revolving around the sun in elliptical orbit .

A small planet is revolving around a massive star in a circular orbit of radius R with a period of revolution T. If the gravitational force between the planet and the star were proportional to R^(-5//2) , then T would be proportional to

A reference frame attached to the earth (a) is an inertial frame by definition (b) can not be an inertial frame because the earth is revolving around the sun (c ) is an inertial frame because Newton's laws are applicable in this frame (d) cannot be an inertial frame because the earth is rotating about its axis

A reference frame attached to the earth a) is an inertial frame by definition b) can not be an inertial frame because the earth is revolving around the sun c) is an inertial frame because Newton's laws are applicable in this frame d) cannot be an inertial frame because the earth is rotating about its axis

Imagine a light planet revolving around a massive star in a circular orbit of raidus r with a a period of revolution T. If the gravitational force of attraction between planet and the star is proportioanl to r^(-5)//^(2) , then find the relation between T and r.

Imagine a light planet revolving around a very massive star in a circular orbit of radius r with a period of revolution T. On what power of r will the square of time period will depend if the gravitational force of attraction between the planet and the star is proportional to r^(-5//2) .

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.

Imagine a light planet revolving around a very massive star in a circular orbit of radius R with a period of revolution T. if the gravitational force of attraction between the planet and the star is proportational to R^(-5//2) , then (a) T^(2) is proportional to R^(2) (b) T^(2) is proportional to R^(7//2) (c) T^(2) is proportional to R^(3//3) (d) T^(2) is proportional to R^(3.75) .

Imagine a light planet revolving around a very massive star in a circular orbit of radius R with a period of revolution T. if the gravitational force of attraction between the planet and the star is proportational to R^(-5//2) , then (a) T^(2) is proportional to R^(2) (b) T^(2) is proportional to R^(7//2) (c) T^(2) is proportional to R^(3//3) (d) T^(2) is proportional to R^(3.75) .

Comets revolve around (a) Earth (b) Sun (c) Venus (d) Moon