What force F must be applied so that `m_(1)` and `m_(2)` are at rest on `m_(3)` in

When force F applied on m_(1) and there is no friction between m_(1) and surface and the coefficient of friction between m_(1)and m_(2) is mu. What should be the minimum value of F so that there is on relative motion between m_(1) and m_(2)

State the value of n, l, m_(l) and m_(s) for 4f.

When force F applied on m_(2) and there is no friction between m_(1) and surface and the coefficient of friction between m_(1) and m_(2) is mu. What should be the minimum value of F so that there is no relative motion between m_(1) and m_(2)

When force F applied on m_(1) and surface. Is mu_(1) and the coefficient of friction between m_(1) and m_(2) is mu_(2). What should be the minimum value of F so that there is no relative motion between m_(1) and m_(2).

Two bars of masses m_(1) and m_(2) connected by a non - deformed light spring rest on a horizontal plane. The coefficient of friction between the bars and the surface is equal to mu . What minimum constant force has to be appled in the horizontal direction to the bar of mass m_(1) in order to shift the other bar?

Two masses m_(1) and m_(2) . Which are connected with a light string, are placed over a frictionless pulley. This set up is placed over a weighting machine, as shown. Three combination of masses m_(1) and m_(2) are used, in first case m_(1)=6 kg and m_(2)=2kg in second case m_(1)=5kg and m_(2)=3kg and in third case m_(1)=4kg and m_(2)=4kg .Masses are held stationary initiallly and then released. If the readings of the weighing machine after the release in three cases are W_(1) , W_(2) and W_(3) respectively then :-

In the figure masses m_(1),m_(2) and M are kg. 5 kg and 50 kg respectively. The co-efficient of friction between M and ground is zero. The co-efficient of friction between m_(1) and M and that between m_(2) and ground is 0.3. The pulleys and the string are massless. The string is perfectly horizontal between P_(1) and m_(1) and also between P_(2) and m_(2). The string is perfectly verticle between P_(1) and P_(2). An externam horizontal force F is applied to the mass M. Take g=10m//s^(2). (i) Drew a free-body diagram for mass M, clearly showing all the forces. (ii) Let the magnitude of the force of friction between m_(1) and M be f_(1) and that between m,_(2) and ground be f_(2). For a particular F it is found that f_(1)=2f_(2). Find f_(1) and f_(2). Write down equations of motion of all the masses. Find F, tension in the string and accelerations of the masses.

A shell at rest on a smootyh horizontal surface explodes into two fragments of masses m_(1) and m_(2) . If just after explosion, m_(1) move with speed u, then work done by internal forces during explosion is :-

Three different objects of masses m_(1) , m_(2) and m_(2) are allowed to fall from rest and from the same point O along three different frictionless paths. The speeds of three objects on reaching the ground will be: