Suppose the smaller pulley of the previous problem has its radius 5.0 cm and moment of inertia 0.10 kg-m^2. Find the tension in the part of the string joiningk the pulleys.

Solve the previous problem if the pulley has a moment of inertia I about its axis and the string does not slip over it.

The descending pulley shown in figure has a radius 20 cm and moment of inertia 0.20 kg-m^2. The fixed pulley is light and the horizontal plane frictionless. Find the acceleration of the block if its mass is 1.0 kg.

The descending pulley shown in figure has a radius 20 cm and moment of inertia 0.20 kg-m^2. The fixed pulley is light and the horizontal plane frictionless. Find the acceleration of the block if its mass is 1.0 kg.

The descending pulley shown in figure has a radius 20 cm and moment of inertia 0.20 kg-m^2. The fixed pulley is light and the horizontal plane frictionless. Find the acceleration of the block if its mass is 1.0 kg.

The pulleys in figure are identical, each having a radius R and moment of inertia I. Find the acceleration of the block M.

The pulleys in filgure are identical, each having a radius R and moment of inertia I. Find the acceleration of the block M.

The pulleys in figure are identical, each having a radius R and moment of inertia I. Find the acceleration of the block M.

The pulley shown in figure has a radius of 20 cm and moment of inertial 0.2 kg-m^2. The string going over it is attached at one end to a vertical sprign of spring constant 50 N/m fixed from below and supports a 1 kg mas at other end. The system is released from rest with the spring at its natural length. Find the speed of the block when it has desceds through 10 cm. Take g=10 m/s^2 .