A body is slipping from an inclined plane of height h and length l . If the angle of inclination is `theta` , the time taken by the body to come from the top to the bottom of this inclined plane is

An inclined plane of height h and length l have the angle of inclination theta . The time taken by a body to come from the top of the bottom of this inclined plane will be

A body is allowed to slide from the top along a smooth inclined plane of length 5m at an angle of inclination 30^(@) .If g=10ms^(-2) , time taken by the body to reach the bottom of the plane is

A spherical object of mass m and radius R is released from the top of a smooth inclined plane of height h and angle of inclination is 37° . The radius of gyration of the object is K. The speed of object at the bottom of inclined plane is

A block is released from top of a smooth inclined plane.It reaches the bottom of the plane in 6 sec.The time taken by the body to cover the first half of the inclined plane is:

A frictionless inclined plane of length l having inclination theta is placed inside a lift which is accelerating downward with on acceleration a (ltg) . If a block is allowed to move down the inclined plane, from rest, then the time taken by the block to slide from top of the inclined plane to the bottom of the inclined plane is

A body slides down a smooth inclined plane of height h and angle of inclination 30^(@) reaching the bottom with a velocity v .Without changing the height, if the angle of inclination is doubled, the velocity with which it reaches the bottom of the plane is

A block is released from top of a smooth inclined plane It reaches the bottom of the plane in sqrt2s The time taken (in second) by the body to cover Ist half of inclined plane is .

A sphere and circular disc of same mass and radius are allowed to roll down an inclined plane from the same height without slipping. Find the ratio of times taken by these two to come to the bottom of incline :

A block released from rest from the tope of a smooth inclined plane of angle of inclination theta_(1) = 30^(@) reaches the bottom in time t_(1) . The same block, released from rest from the top of another smooth inclined plane of angle of inclination theta_(2) = 45^(@) reaches the bottom in time t_(2) . Time t_(1) and t_(2) are related as ( Assume that the initial heights of blocks in the two cases are equal ).

A body is in equilibrium on a rough inclined plane undr its own weight. If the angle of inclination of the inclined plane is alpha and the angle of friction is lambda , then