In figure `m_1=5 kg, m_2=2kg and F=1N.` Find the acceleration of either block. Describe the motion of `m_1` if the string breaks but F continues to act.

Let m_1=1 kg, m_2=2kg and m_3=3kg is figure. Find the acceleration of m_1, m_2 and m_3 . The string from the upper pulley to m_1 is 20 cm when the system is released from rest. How long will it take before m_1 strikes the pulley?

The block shown in figure has a mass M and descends with an acceleration a. The mass of the string below the point A is m. Find the tension of the string at the point A and at the lower end.

If the tension in the string in the figure. Is 16 N and the acceleration of each block is 0.5 m/s^2 , find the friction coefficients at the two contacts with h blocks.

In figure, k = 100 N//m, M = 1kg and F = 10 N (a) Find the compression of the spring in the equilibrium position (b) A sharp blow by some external agent imparts a speed of 2 m//s to the block towards left. Find the sum of the potential energy of the spring and the kinetic energy of the block at this instant. (c) Find the time period of the resulting simple harmonic motion. (d) Find the amplitude.

Consider the situation shown in figure. Calculate a. the acceleration of the 1.0 kg blocks, b. the tension in the strilng connecting the 1.0 kg blocks and c. the tension in the stting attached to 0.50 kg.

Describe the motion of the mass m shown in figure. The walls and the block are elastic.

A block of mass M is pulled on a smooth horizontal table by a string making an angle theta with the horizontal as shown in figure. If the acceleration of the block is a , find the force applied by the string and by the table N on the block.

If same force is acting on two masses m_1 and m_2 and the accelerations of two bodies are a_1 and a_2 respectively, then

Suppose the rod in the previous problem has a mass of 1 kg distributed uniformly over its length. a. find the initial angular acceleration of the rod. b. Find the tension in the supports to the blocks of mass 2 kg and 5kg .

Three particles of masses m_1 = 1 kg, m_2 = 2 kg " and " m_2 = 3 kg are placed at the corners of an equilateral triangle of side 1m as shown in Figure. Find the position of center of mass.