A cubical block of side a is moving with velocity `v` on a horizontal smooth plane as shown in Fig. It hits a ridge at point `O`. The angular speed of the block after it hits `O` is

A cubical block of side a is moving with velocity V on a horizontal smooth plane as shown in Figure. It hits a ridge at point O. The angular speed of the block after it hits O is

A cubical block of side a is moving with velocity V on a horizontal smooth plane as shown in Figure. It hits a ridge at point O. The angular speed of the block after it hits O is

A small block slides with velocity v_0=0.5sqrt(gr) on the horizontal frictiohnless surface as shown in the fig. the block leaves the surface at point C. The angle theta in the figure is:

A block of mass m moving with velocity v_(0) on a smooth horizontal surface hits the spring of constant k as shown. The maximum compression in spring is

A particle is moving with constant speed v in xy plane as shown in figure. The magnitude of its angular velocity about point O is

A ball of mass moving with constant velocity u collides with a smooth horizontal surface at O as shown in Fig. Neglect gravity and friction. The y -axis is drawn normal to the horizontal surface at the point of impact O and x -axis is horizontal as shown. About which point will the angular momentum of ball be conserved?

A ball is projected from a point A with some velocity at an angle 30^@ with the horizontal as shown in (Fig. 5.204). Consider a target at point B . The ball will hit the target if it thrown with a velocity v_0 equal to. .

A block of mass m is moving in a circle of radius R with speed v inside a smooth cone as shown in figure. Choose the wrong options

Two blocks A and B of masses in and 2m , respectively, are connected with the help of a spring having spring constant, k as shown in Fig. Initially, both the blocks arc moving with same velocity v on a smooth horizontal plane with the spring in its natural length. During their course of motion, block B makes an inelastic collision with block C of mass m which is initially at rest. The coefficient of restitution for the collision is 1//2 . The maximum compression in the spring is

A uniform rod of mass m and length l is applied pivoted at point O . The rod is initially in vertical position and touching a block of mass M which is at rest on a horizontal surface. The rod is given a slight jerk and it starts rotating about point O this causes the block to move forward as shown The rod loses contact with the block at theta=30^(@) all surfaces are smooth now answer the following questions. Q. The velocity of block when the rod loses contact with the block is