In the arrangement shown `m_1= 300kg, m_2 = 400kg` the system is in equilibrium

A system containing masses and pulleys connected on an inclined plane is shown in the figure If the system is in equilibrium then the value of m is

The blocks A and B shown in the figure have masses M_A = 5 kg and M_B = 4 kg . The system is released from rest. The speed of B after A has travelled a distance 1 m along the incline is

A block A of mass 3kg and another block B of mass 2 kg are connected by a light inextensible string as shown in figure. If the coefficient of friction between the surface of the table and A is 0.5. What maximum mass C is to be placed on A so that the system is to be in equilibrium? (g = 10 m//s^2)

In the arrangement shown in the figure all surfaces are frictionless, the masses of the block are m_1 = 20kg and m_2 = 30kg. The accelerations of masses m_1 and m_2 will be if F = 180N.

The masses m_(1)=10 kg m_(2)=5 kg are connected by a ideal string as shown in figure. The coefficient of friction m_(1) and the surface is mu=0.2 .Assuming that the system is released from rest. Calculate the velocity of block when m_(2) has descended by 4m? [g=10ms^(-2)]

If m_1 = 10 kg, m_2 = 4kg and m_3=2kg the tension in the string connecting m_1 and m_2 is ,