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.

System shown in figure is released from rest . Pulley and spring is massless and friction is absent everywhere. The speed of 5 kg block when 2 kg block leaves the contact with ground is (force constant of spring k = 40 N//m and g = 10 m//s^(2))

System shown in figure is released from rest . Pulley and spring is mass less and friction is absent everywhere. The speed of 5 kg block when 2 kg block leaves the constant of with ground is (force constant of spring k = 40 N//m and g = 10 m//s^(2))

In the situation shown in figure F=500 newton applied on the pulley m_(1)=50 kg and m_(2) = 10 kg and pulley and strings are massless and frictionless. Then the acceleration of the pulley is : [g = 10 m//s^(2)]

In the system shown in fig., m_(A)=4m , m_(B)=3m , and m_(c)=8m . Friction is absent everywhere. String is inextensible and light. If the system is released from rest, then Acceleration of Block B is

In the system shown in fig., m_(A)=4m , m_(B)=3m , and m_(c)=8m . Friction is absent everywhere. String is inextensible and light. If the system is released from rest, then Acceleration of Block B is

In the system shown in fig., m_(A)=4m , m_(B)=3m , and m_(c)=8m . Friction is absent everywhere. String is inextensible and light. If the system is released from rest, then Acceleration of Block A in horizontal direction is

In the system shown in fig., m_(A)=4m , m_(B)=3m , and m_(c)=8m . Friction is absent everywhere. String is inextensible and light. If the system is released from rest, then Acceleration of block C is