A particle block of mass 'm' is in equilibrium being supported by light strings AB, BC and CD as shown. AB 5a, CB=3a, AC= 4a. A horizontal force F = ing in the plane of ABC acts parallel to A Bas shown. Then,

Two blocks of masses m and M are connected by an inextensible light string as shown in the figure. When a constant horizontal force F acts on the block of the mass M , then tension in the string is : (Assume that constact between the ground and the two blocks are frictionless) and blocks will not topple. (Given: m = 1 kg, M = 4 kg, F = 10 N, theta = 60^(@) )

Two blocks of masses m and M are connected by an inextensible light string as shown in the figure. When a constant horizontal force F acts on the block of the mass M, then tension in the string: (Assume that contact between the ground and the two blocks are frictionless) (given m=1kg,M=4kg,F=10N,theta=60^(@))

Two blocks of masses m and M are connected by an inextensible light string . When a constant horizontal force acts on the block of mass M. The tension in the string is

In the figure shown a ring of mass M and a block of mass m are in equilibrium. The string is light and pulley P does not offer any friction and coefficient of friction between pole and M is mu. The frictional force offered by the pole to M is

Two blocks A and B of the same mass are joined by a light string and placed on a horizontal surface. An external horizontal force P acts on A. The tension in the string is T. The forces of static friction acting on A and B are F_(1) and F_(2) respectively. The limiting value of F_(1) and F_(2) is F_(0) . As P is gradually increased.

Two blocks of masses 10 kg and 20 kg are connected by a massless string and are placed on a smooth horizontal surface as shown in the figure. If a force F=600 N is applied to 10 kg block, then the tension in the string is

A block of mass m is placed on a rough horizontal floor and it is pulled by a ideal string by a constant force F as shown. As the block moves towards right the friction force on block

A block is kept on a rough horizontal surface as shown. Its mass is 2 kg and coefficient of friction between block and surface (mu)=0.5. A horizontal force F is acting on the block. When

A ball of mass m kept at the corner as shown in the figure, is acted by a horizontal force F. The correct free body diagram of ball is

In a triangle ABC, AB = 5 , BC = 7, AC = 6. A point P is in the plane such that it is at distance '2' units from AB and 3 units form AC then its distance from BC