For the system shown in the figure, the pulleys are light and frictionless. The tension in the string will be (Assume all surfaces to be smooth)

For the system shown in figure, the tensions in the string

Two blocks, each having a mass M, rest on frictionless surfaces as shown in the figure. If the pulleys are light and frictionless and M on the incline is allowed to move down, then the tension in string will be

For the system shown in the figure, the inclined plane is fixed, all the pulleys are light and friction is absent every where.The tension in the string will be

In the arrangement shown, all the surface are smooth, strings and pulleys are light. Find the tension in the string.

Find the natural frequency of oscillation of the system as shown in figure. Pulleys are massless and frictionless. Spring and string are also massless. (Take pi^(2)=10 )

Find the acceleration of two masses as shown in figure . The pulley are light and frictionless and string are light and frictionless and string are light and inextensible.

Find the natural frequency of the system shown in figure. The pulleys are smooth and massless.

In the system shown in the figure, which the following is correct? (Pulleys and strings are of negligible mass)

For the arrangement shown in figure, angle theta for which tension T_1 in the left string will be minimum is (Pulley and strings are ideal)

The intial configuration of the system is as shown in the figure. The string and the pulley are light. The bob is released and the string starts wrapping around the pulley. (The pulley is held in place by a force applied at the centre) Find the rate r at which the length of the string warpped around the pulley increaes (as a function of theta ).