In the figure shown rod `AB` is light and rigid while rod `CD` is also rigid and hinged at midpoint `O` Rod can rotate without friction about `O`. The time period of small oscillation of rod `CD` is `T=2pisqrt(m/(nk))`. Where `m` is mass of rod `CD` and `k` is spring constant of each spring. The value of `n` is

A uniform rod of mass m and length l is suspended about its end. Time period of small angular oscillations is

In the figure shown, the spring are connected to the rod at one end and at the midpoint. The rod is hinged at its lower end. Rotational SHM of the rod (Mass m , length L ) will occur only if-

A uniform rod ofmass M and length L is hanging from its one end free to rotate in a veritcal plane.A small ball of equal mass is attached of the lowe end as shown. Time period of small oscillations of the rod is

A particle of mass m in suspended at the lower end of a thin negligible mass. The upper end of the rod is free to rotate in the plane of the page about a horizontal axis passing through the point O . The spring is underformed when the rod is vertical as shown in fig. If the period of oscillation of the system is pisqrt((L)/(n)) , when it is slightly displaced from its mean position then find n . Take k = (9mgL)/(l^(2)) and g = 10m//s^(2) .

Two identical small discs each of mass m placed on a frictionless horizontal floor are connected with the help of a light spring of force constant k. The discs are also connected with two light rods each of length 2sqrt(2)m that are pivoted to a nail driven into the floor as shown as shown in the figure by a top view of the situation. If period of small oscillations of the system is 2pi sqrt((m//k)) , find relaxed length (in meters) of the spring.

In the figure shown, PQ is a uniform sphere of mass M and radius R hinged at point P , with PQ as horizontal diameter. QT is a uniform horizontal rod of mass M and length 2R rigidly attached to the sphere at Q, supported by a vertical spring of spring constant k. If the system is in equilibrium, then the potential energy stored in the spring is

A rod of length l and mass m , pivoted at one end, is held by a spring at its mid - point and a spring at far end. The spring have spring constant k . Find the frequency of small oscillations about the equilibrium position.

A uniform rod of mass 200 grams and length L = 1m is initially at rest in vertical position. The rod is hinged at centre such that it can rotate freely without friction about a fixed horizontal axis passing through its centre. Two particles of mass m = 100 grams each having horizontal velocity of equal magnitude u = 6 m/s strike the rod at top and bottom simultaneously as shown and stick to the rod. Find the angular speed (in rad/sec.) of rod when it becomes horizontal.

In the figure shown, the cart of mass 6m is initially at rest. A particle of mass in is attached to the end of the light rod which can rotate freely about A . If the rod is released from rest in a horizontal position shown, determine the velocity v_(rel) of the particle with respect to the cart when the rod is vertical.

A rod of mass m and length L is kept on a horizontal smooth surface. The rod is hinged at its one end A . There are two springs, perpendicular to the rod, kept in the same horizontal plane. The spring of spring constant k is rigidly attached to the lower end of rod and spring of spring constant 12k just touches the rod at its midpoint C , as shown in the figure. If the rod is slightly displaced leftward and released then, the time period for small osciallation of the rod will be