Find the distance between centre of gravity and centre of mass of a two particle system attached to the ends of a light rod. Each particle has same mass. Length of the rod is R, where R is the radius of earth.

The centre of mass of a system of particles is at the origin. It follows that:

If the mass of moon is (M)/(81) , where M is the mass of earth, find the distance of the point where gravitational field due to earth and moon cancel each other, from the centre of moon. Given the distance between centres of earth and moon is 60 R where R is the radius of earth

If the mass of moon is (M)/(81) , where M is the mass of earth, find the distance of the point where gravitational field due to earth and moon cancel each other, from the centre of moon. Given the distance between centres of earth and moon is 60 R where R is the radius of earth

Where does the centre of mass of two particle system lie, if one particle is more massive than the other ?

A tuning is dug along the diameter of the earth. There is particle of mass m at the centre of the tunel. Find the minimum velocity given to the particle so that is just reaches to the surface of the earth. (R = radius of earth)

Two particles of masses m_1 and m_2 are joined by a light rigid rod of length r. The system rotates at an angular speed omega about an axis through the centre of mass of the system and perpendicular to the rod. Show that the angular momentum of the system is L=mur^2omega where mu is the reduced mass of the system defined as mu=(m_1m_2)/(m_1+m_2)

In the figure shown, the cart of mass 6m is initially at rest. A particle of mass in is attached to the end of the light rod which can rotate freely about A . If the rod is released from rest in a horizontal position shown, determine the velocity v_(rel) of the particle with respect to the cart when the rod is vertical.

Find the moment of inertia A of a spherical ball of mass m and radius r attached at the end of a straight rod of mass M and length l , if this system is free to rotate about an axis passing through the end of the rod (end of the rod opposite to sphere).

Find centre of mass of given rod of linear mass density lambda=(a+b(x/l)^2) , x is distance from one of its end. Length of the rod is l .

The y co - ordinate of the centre of mass of the system of three rods of length 2a and two rods of length a as shown in the figure is (Assume all rods to be of uniform density)