In the system in the figure `m_(1)gtm_(2)` system is held at rest by thread `BC`. Just after the thread BC is burnt:

A system of two identical rods (L-shaped) of mass m and length l are resting on a peg P as shown in the figure. If the system is displaced in its plane by a small angle theta ,find the period of oscillations:

On an inclined plane making an angle theta with the horizontal plane, a solid cylinder of mass m_(1) is connected to a block of mass m_(2) by means of a light chord which is parallel to incline plane . The coefficient of friction between block and incline and between cylinder and incline is equal to mu . the system is held at rest & then released . If cylinder & block move together and cylinder perform pure rolling & tension in string is non zero then Minimum value of mu for which cylinder will not slip ?

On an inclined plane making an angle theta with the horizontal plane, a solid cylinder of mass m_(1) is connected to a block of mass m_(2) by means of a light chord which is parallel to incline plane . The coefficient of friction between block and incline and between cylinder and incline is equal to mu . the system is held at rest & then released . If cylinder & block move together and cylinder perform pure rolling & tension in string is non zero then Acceleration of block will be :

In the given figure both the bocks have equal mass. When the thread is cut, which of the following statements give correct discription immediately after the thread is cut?

Simple Atwood Machine as System of Particles The system shown in the figure is known as simple Atwood machine. Initially the masses are held at rest and then let free. Assuming mass m_(2) more than the mass m_(1) , find acceleration of mass center and tension in the string supporting the pulley.

Two particles each of mass m are connected by a light inextensible string and a particle of mass M is attached to the midpoint of the string. The system is at rest on a smooth horizontal table with string just taut and in a straight line. The particle M is given a velocity v along the table perpendicular to the string. Prove that when the two particles are about to collide : (i) The velocity of M is (Mv)/((M + 2m)) (ii) The speed of each of the other particles is ((sqrt2M (M + m))/((M + 2m)))v .

Figure illustrates an aligned system consisting of three thin lenses. The system is located in air. Determine: (a) the position of the point of convergence of a parallel incoming from the left after passing through the system, (b) the distance between teh first lens and a point lying on the axis to the left of the system, at which that point and its image are located symmetrically with respect to the lens system.

A mass of 2 kg suspended with thread AB (figure). Thread CD of the same type is attached to the other end of 2 kg mass. Lower thread is pulled gradually, harder and harder in the downward direction, so as to apply force on AB. Which of the threads will break and why ?

In the given figure, Find mass of the block A, if it remains at rest, when the system is released from rest. Pulleys and strings are massless. [g=10m//s^(2)]