A simple pendulum `A` and `a` homogeneous rod `B` hinged at its enda are released from horizontal position as shown in figure.

A uniform thin rod of length l and mass m is hinged at a distance l//4 from one of the end and released from horizontal position as shown in Fig. The angular velocity of the rod as it passes the vertical position is

Two masses each of m are attached at mid point B and end point C of massless rod AC which is hinged at A . It is released from horizontal position as shown. Find the force at hinge A when rod becomes vertical. .

A light rod carries three equal masses A, B and C as shown in figure. Find the velocity of B in vertical position of rod, if it is released from horizontal position. As shown in figure.

A composite rod of mass 2m and length 2l comprises two indentica rods joined end to end at P . The composite rod hinged at one of its ends is kept horizontal as shown in the figure. If it is realeased from rest. a. find its angular speed when it becomes vertical. b. If the lower rod gets detached with the upper rod due to centrifugal effect at their joint P , at the vertical position of the composite rod, find their linear and angular velocities just after their separation.

A rod hinged at one end is released from the horizontal position as shown in the figure. When it becomes vertical its lower half separates without exerting any reaction at the breaking point. The find the maximum angle theta made by the hinged upper half with the vertical. .

The length of a simple pendulum of 0.4 m. The bob of the pendulum is drawn aside till the string is horizontal, it is then released from this horizontal position, What will be its velocity when it reached the lowest point in its swing ? (g = 9.8 m//s^(2)) [Hint : Loss in potential energy = gain in kinetic energy]

A rod of mass m and length l is hinged at 'its' end and released from rest in position shown. Find the force exerted by the hinge when the rod becomes horizontal