A body with zero initial velocity slips from the top of an inclined plane forming an angle `alpha` with the horizontal. The coefficient of friction `mu` between the body and the plane increases with the distance s from the top according to the law `mu = bs`. After what distance the body will stop.

A body with zero initial velocity slips from the top of an inclined plane forming an angle alpha with the horizontal. The coefficient of friction mu between the body and the plane increases with the distance l from the top according to the law mu = bl . The body stops before it reaches the end of the plane. Determine the time t from the beginning of motion of the body to the moment when it comes to rest.

A body is sliding down an inclined plane forming an angle 30^(@) with the horizantal. If the coefficient of friction is 0.3 then acceleration of the body is

A body of mass m slides down an inclined plane making an angle of 45^(@) with the horizontal. If the coefficient of friction between the body and the plane be 0.3, the acceleration of the body is approximately equal to :

A body of mass 5xx10^(-3) kg is launched upon a rough inclined plane making an angle of 30^(@) with the horizontal. Obtain the coefficient of friction between the body and the plane if the time of ascent is half of the time of descent.

A body is moving down a long inclined plane in inclination 45^(@) with horizontal. The coefficient of friction between the body and the plane varies as mu=x//2 , where x is the distance moved down the plane. Initially x=0 & v=0 .

A body of mass 2 kg is placed on rough horizontal plane. The coefficient of friction between body and plane is 0.2 Then,

A body is moving down a long inclined plane of inclination 45^(@) with horizontal. The coefficient of friciton between the body and the plane varies as mu = x//2 , where x is the distance moved down the plane. Initially x=0 & v=0