In the arrangement shown in fig `m_(1)=1kg, m_(2)=2 kg` Pulleys are massless and string are light. For what value of M the mass `m_(1)` moves with constant velocity (neglect friction):

In the arrangement shown in fig. m_(1)=1kg, m_(2)=2 kg . Pulleys are massless and strings are light. For what value of M, the mass m_(1) moves with constant velocity.

In the arrangement shown in figure m_(1)=1kg, m_(2)=2kg , pullyes are massless and strings are light. For what value of M the mass m_(1) moves with constant velocity? (Neglect friction)

In the arrangment as shown below m_(1) = 1 kg, m_(2) = 2 kg . Pulleys are massless and strings are light . For what value of M the mass m_(1) moves with constant velocity . ( Neglect Friction)

In the system shown in figure m_(B)=4kg , and m_(A)=2kg . The pulleys are massless and friction is absent everywhere. The acceleration of block A is.

In the arrangement , shown below pulleys are massless and frictionless and threads are inextensible , block of mass m_(1) will remain at rest if

In the arrangement shown in Figure, m_A=2kg and m_B=1kg . String is light and inextensible. Find the acceleration of centre of mass of both the blocks. Neglect friction everywhere.

In the arrangement shown the fixed pulley is massless and frictionless. If the acceleration of block of mass 1kg is (30)/(x)m//s^(2) . Find the value of x .

In the figure shown m_(1)=1 kg,m_(2)=2kg , pulley is ideal. At t=0 , both masses touches the ground and string is taut. A force F=2t is applied to pulley (t is in second) then (g = 10 m//s^(2)) :

In the system shown in fig., all pulleys are mass less and the string is inextensible and light. (a) After the system is released, find the acceleration of mass m_(1) (b) If m_(1) = 1 kg, m_(2) = 2 kg "and" m_(3) = 3 kg then what must be value of mass m_(4) so that it accelerates downwards?