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.

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 fig. both pulleys and the string are massless and all the surfaces are frictionless. Given m_(1)=1kg, m_(2)= 2kg, m_(3)=3kg . The acceleration of m_(1) is

In fig. both pulleys and the string are massless and all the surfaces are frictionless. Given m_(1)=1kg, m_(2)= 2kg, m_(3)=3kg . The acceleration of m_(3) is

Three blocks of masses m_1, m_2 and m_3 are connected as shown in the figure. All the surfaces are frictionless and the string and the pulleys are light. Find the acceleration of m_1

In the figure shown, the acceleration of block of mass m_(2) is 2m//s^(2) . The acceleration of m_(1) :

In the arrangement shown in figure pulleys are mass of block A,b and C is m_(1) = 5 kg m_(2) = 4 kg and m_(3) = 2.5 kg respectively .Co-efficient acceleration of friction for both the plane is mu = 0.50 Calculate acceleration of which block when system is released from rest

All the surfaces are smooth as shown in figure. The acceleration of mass m relative to wedge is :

In the arrangement shown in fig. the block of mass m=2kg lies on the wedge of mass M=8kg . The initial acceleration of the wedge, if the surfaces are smooth, is

In the system shown all the surfaces are frictionless while pulley and string are massless. The mass of block A is 2m and that of block B is m. The acceleration of block B immediately after system is released from rest is

Two blocks of masses m_1 and m_2 are connected as shown in the figure. The acceleration of the block m_2 is :