Assertion : Mass of the rod AB is `m_(1)` and of particle P is `m_(2)`. Distance between centre of rod and particle is r. Then the gravitational force between the rod and the particle is
`F=(Gm_(1)m_(2))/(r^(2))`

Reason : The relation `F=(Gm_(1)m_(2))/(r^(2))` can be applied directly only to find force between two particles.

The gravitational force between a H-atom and another particle of mass m will be given by Newton's law: F=G (M.m)/(r^(2) , where r is in km and

The gravitational force between a H-atom and another particle of mass m will be given by Newton's law: F=G (M.m)/(r^(2) , where r is in km and

A particle of mass m is kept on the axis of a fixed circular ring of mass M and radius R at a distance x from the centre of the ring. Find the maximum gravitational force between the ring and the particle.

A mass m is at a distance a from one end of a uniform rod of length l and mass M. Find the gravitational force on the mass due to the rod.

A mass m is at a distance a from one end of a uniform rod of length l and mass M. Find the gravitational force on the mass due to tke rod.

Assertion : The centres of two cubes of masses m_(1) and m_(2) are separated by a distance r. The gravitational force between these two cubes will be (Gm_(1)m_(2))/(r^(2)) Reason : According to Newton's law of gravitation, gravitational force between two point masses m_(1) and m_(2) separated by a distance r is (Gm_(1)m_(2))/(r^(2)) .

The gravitational force F between two masses m_(1) and m_(2) separeted by a distance r is given by F = (Gm_(1)m_(2))/(r^(2)) Where G is the universal gravitational constant. What are the dimensions of G ?

If gravitational attraction between two points masses be given by F=G(m_(1)m_(2))/(r^(n)) . Then the period of a satellite in a circular orbit will be proportional to

A particle of mass m is situated at a distance d from one end of a rod of mass M and length L as shown in diagram. Find the magnitude of the gravitational force between them