The masses of A,B and C in the figure (Fig. 5.24) are `m_(A)`=4 kg, `m_(B)`=2 kg and `m_(C)`=3 kg. The mass of the movable pulley is 1 kg. Show that the acceleration of A is `(9g)/(49)`

m_(A) = 1 kg, m_(B) = 2 kg, m_(C) = 10 kg

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 in the figure pulleys are small, light and frictionless, threads are inextensible and mass of blocks A , B and C is m_(1)=5kg , m_(2)=4kg and m_(3)=2.5kg respectively and co-efficient of friction for both the planes is mu=0.50 . Calculate the acceleration of block A (in m//s^(2) ) when the system is released from rest. ( g=10 m//s^(2) )

In the figure shown, m_(1) = 10kg, m_(2) = 6kg, m_(3) = 4kg. If T_(3) = 40 N, T_(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?

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

Three blocks of masses m_(1)=4kg, m_(2)=2kg, m_(3)=4kg are connected with ideal strings passing over a smooth, massless pulley as shown in figure. The acceleration of blocks will be (g=10m//s^(2))

If m_(1) =10kg,m_(2)=4kg,m_(3) =2kg , the acceleration of system is .