A block is kept on a smooth inclined plane of angle of inclination `theta` that moves with a constant acceleration so that the block does not slide relative to the inclined plane. If the inclined plane stops, the normal contact force offered by the plane on the block changes by a factor

A block is kept on a smooth inclined plane of angle of inclination theta that moves wuth a contact acceleration so that the block does not slide relative to the inclined plane. If the inclined plane stops the normal contact force offered by the plane on the block changes by a factor

A block is kept on a smooth inclined plane of angle of inclination 30^(@) that moves with a constant acceleration so that the block does not slide relative to the inclined plane. Let F_(1) be the the contact force between the block and the plane . Now the inclined plane stops and let F_(2) be the contact force between the two in this case. Then, F_(1)//F_(2) is

A block of mass m is placed on a smooth inclined plane of inclination theta with the horizontal. The force exerted by the plane on the block has a magnitude

A block is released on an smooth inclined plane of inclination theta . After how much time it reaches to the bottom of the plane?

A block of mass m = 3 kg slides on a rough inclined plane of cofficient of friction 0.2 Find the resultant force offered by the plane on the block

A block of mass m is kept on an inclined plane of mass 2m and inclination alpha to horizontal. If the whole system is accelerated such that the block does not slip on the wedge then :

A block can slide on a smooth inclined plane of inclination theta kept on the floor of a lift. When the lift is descending with a retardation a , the acceleration of the block relative to the incline is

The acceleration of 10 kg block on the inclined plane is

A block of mass 10kg is pushed up on a smooth incline plane of inclination 30^(@) , so that it has acceleration 2m//s^(2) . The applied force is