In the system of pulleys shown what should be the value of `m_(1)` such that 100 gm remains at rest : (Take `g = 10 m//s^(2)`)

In the arrangement shown in figure what should be the mass of block A , so that the system remains at rest ? Neglect friction and mass of string.

In the system shown in the adjoining figure, the acceleration of the 1 kg mass is m//s^(2) . (take g = 10 m//s^(2) )

For the equilibrium of the system shown, the value of mass m should be

In the previous problem, suppose m_2=2.0kg and m_3=3.0 kg . What should be the mass m so that it remains at rest?

In the arrangement shown in figure, what should be the mass of block A so that the system remains at rest. Also find force exerted by string on the pulley Q. (g = 10 m//s^(2))

Consider the situation as shown in the figure. Find the maximum value of m_(1)//m_(2) so that the system remains at rest. What will happen if tan theta lt mu ?

Two block of masses m =5kg and M =10kg are connected by a string passing over a pulley B as shown. Another string connect the center of pulley B to the floor and passes over another pulley A as shown. An upwards force F is applied at the center of pulley A . Both the pulleys are massless. Find the acceleration of block m and M , if F is (a) 100N 300N 500N(Take g = 10m//s^(2))

Two smooth blocks of same mass are connected by an inextensible and massless string which is passing over a smooth pulley are kept in a lift is going down with acceleration 'a' as shown in the fig What should be the value of a (in m//s^(2)) so that acceleration of block A w.r.t. ground will be minimum? (g=10m//s^(2))