In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with `x` as `mu=kx`, where `k= tan theta`. A block is released at `O`

Maximum distance traveled by block:

In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with x as mu = kx , where k = tan theta . A block is released at O Maximum distance traveled by the block :

In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with x as mu=kx , where k= tan theta . A block is released at O . The maximum velocity of block will be:

In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with x as mu = kx , where k = tan theta . A block is released at O The maximum velocity of block will be :

In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with x as mu = kx , where k = tan theta . A block is released at O Frictional force acting on the block after it comes to rest :

In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with x as mu=kx , where k= tan theta . A block is released at O Frictional force acting on the block after it comes to rest:

In the adjacent figure, x-axis has been taken down the inclined plane. The coefficient of friction varies with x as mu = kx , where k = tan theta . A block is released at O Frictional acting on the block just before it comes to rest :

In the adjacent figure, x-axis has been taken down the inclined plane and y-axis perpendicular to the inclined plane. Te coefficient friction varies with x as mu = kx , where k = tan theta . A block is released at O. The maximum velocity of block will be

In the adjacent figure, x-axis has been taken down the inclined plane and y-axis perpendicular to the inclined plane. Te coefficient friction varies with x as mu = kx , where k = tan theta . A block is released at O. Frictional force acting on the block just before it comes to rest

A body which was released from rest, slides down on an inclined plane of inclination theta . The coefficient of friction dowh the plane varies as mu = kx where k is a spositive constant and x is the distance moved by the body down the plane. The speed of the body 'v' versus distance 'x' graph will be as :

A body is moving down a long inclined plane of angle of inclination 'theta ' for which the coefficient of friction varies with distance x as mu (x) = kx , where k is a constant . Here x is the distance moved by the body down the plane . The net force on the body will be zero at a distance x_(0) is given by ..........