A particle of maas m is attched to a light string of length l, the other end of which is fixed. Initially the string is kept horizontal and the particle is given an upwrd velocity v. The particle is just able to complete a circle

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 .

A particle of mass 2m is connected by an inextensible string of length 1.2 m to a ring of mass m which is free to slide on a horizontal smooth rod. Initially the ring and the particle are at the same level with the string taut. Both are then released simultaneously. The distance in meter moved by the ring when the string becomes veritcal is :-

A particle of mass m is tied to light string and rotated with a speed v along a circular path of radius r. If T=tension in the string and mg= gravitational force on the particle then actual forces acting on the particle are

Two particles, each of mass m, are connected by a light inextensible string of lenthe 2l . Initially they lie on a smooth horizontal table at points A and B distant l apart. The particle at A is projected across the table with velocity u. Find the speed with which the second particle begins to move if the direction of u is :- (i) along BA. (ii) at an angle of 120^(@) with AB (iii) perpendicular to AB. In each case calculate (in teerms of m and u) the impulsive tension in the string.

A bead can slide on asmooth straight wire and a particle of mass m attached to the bead by a light string of length L. The particle is held in contact with the wire and with the string taut and is then let fall. If the bead has mass 2m then when the string makes an angle theta with the wire, the bead will have slipped a dsitance.

A particle P of mass m is attached to a vertical axis by two strings AP and BP of length l each. The separation AB=l. P rotates around the axis with an angular velocity omega . The tensions in the two strings are T_(1) and T_(2)

A heavy particle is tied ot the end A of a string of length 1.6m . Its other end O is fixed. It revolves as a conical pendulum with the string making 60^(@) with the vertical. Then (g=10m//s^(2))

A bob of mass m is attached at one end of a string of length l other end of the string is fixed at point O . Bob is rotating in a circular path of radius l in horizontal plane about O with constant speed v , as shown in the figure. The average force exterted by string on the bob during its :- (A) half revolution will be (mv^(2))/(pil) (B) half revolution will be (2mv^(2))/(pil) (C) one fourth revolution will be (sqrt2mv^(2))/(pil) (D) one revolution will be zero Select correct alternative :-

A particle of mass m is attached to one end of a mass-less spring of force constant k, lying on a frictionless horizontal plane. The other end of the spring is fixed. The particle starts moving horizontally from its equilibrium position at time t=0 with an initial velocity u_0 . when the speed of the particle is 0.5u_0 , it collides elastically with a rigid wall. After this collision