In the adjoining figure all surface are frictionless . What force `F` must be applied to `M_(1)` to keep `M_(3)` free from rising or falling?

In the adjoining figure all surface are frictionless . What force F must by applied to M_(1) to keep M_(3) free from rising or falling?

A yo-yo, arranged as shown, rests on a frictionless surface. When a force F is applied to the string, the yo-yo

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

Consider the situation shown in figure. Both the pulleys and the strings are light and all the surfaces are frictionless. Calculate (a) the acceleration of mass M, (b) tension in the string PQ and (c ) force exerted by the pulley P.

A unifrom cube of mass m and side a is placed on a frictionless horizontal surface .A vertical force F is applied to the edge as shown in figure ,match the following (most appropriate choice )

Three blocks of masses m_(1), m_(2) and M are arranged as shown in figure. All the surfaces are fricationless and string is inextensible. Pulleys are light. A constant force F is applied on block of mass m_(1) . Pulleys and string are light. Part of the string connecting both pulleys is vertical and part of the strings connecting pulleys with masses m_(1) and m_(2) are horizontal. {:((P),"Accleration of mass " m_(1),(1) F/(m_(1))),((Q),"Acceleration of mass" m_(2),(2) F/(m_(1)+m_(2))),((R),"Acceleration of mass M",(3) "zero"),((S), "Tension in the string",(4) (m_(2)F)/(m_(1)+m_(2))):}

find the acceleration of the block of mass M in the situation shown in figure. All the surfaces are frictionless and the pulleys and the string are light.

Two blocks of masses m_(1) and m_(2) are connected with a light spring of force constant k and the whole system is kept on a frictionless horizontal surface. The masses are applied forces F_(1) and F_(2) as shown in fig. At any time the blocks have same acceleration a_(0) but in opposite direction. Now answer the following : If F_(2) is removed at this moment, then just after the acceleration of m_(2) is

A block of mass M is placed on the top of a bigger block of mass 10 M as shown in figure. All the surfaces are frictionless. The system is released from rest, then the distance moved by the bigger block at the instant the smaller block reaches the ground :

Two blocks of masses m_(1) and m_(2) are connected with a light spring of force constant k and the whole system is kept on a frictionless horizontal surface. The masses are applied forces F_(1) and F_(2) as shown in fig. At any time the blocks have same acceleration a_(0) but in opposite direction. Now answer the following : the value of spring force is