A stick of length `L = 2.0 m` is leaned against a wall as shown. It is released from a position when `theta = 60^(@)`. The end A of the stick remains in contact with the wall and its other end B remains in contact with the floor as the stick slides down. Find the distance travelled by the centre of the stick by the time it hits the floor.

his stick in its face. But this

A meter stick is hold vertically with one end on the floor of the sticks does not move. The velocity of the other end when it hits the floor, will be

A ladder of length L is slipping with its ends against a vertical wall and a horizontal floor. At a certain moment, the speed of the end in contact with the horizontal floor is v and the ladder makes an angle theta=30^@ with horizontal. Then, the speed of the ladder's centre of mass must be

A stick of length 100cm rests against a vertical walland the horizontal floor.If the foot of the stick slides with the constant velocity of 10cm/s then find the magnitude of the velocity of the middle point of the stick when it is inclined at with the floor.

The M.I. of a thin uniform stick of mass 9 gm about an axis passing through one end perpendicular to the length of a meter stick is

Two blocks of mass M and 2M are connected to the two ends of a light, inextensible string passing over an ideal pulley as shown in figure. The system is released from rest. (a) One second after the system is released, a particle of mass M hits the block of mass M and sticks to it. The particle hits the block with a speed of 10 m/s while travelling downward. Find the total distance travelled by block of mass 2M after it is released. (b) One second after the system is released, a particle of mass 2M hits the block of mass M and sticks to it. The particle hits the block with a speed of 10 m/s while travelling in upward direction. Find distance travelled by the block of mass 2M after it is released to the time it comes to rest for the first time (g = 10 m//s)^(2)