Two light verticle springs `1` and `2` of stiffness `K` and `2K` are connected by a `1` light horizontal rod. `A` bead of chewing gum of mass `'m'` is placed gently at the mid point of the rod and lowered slowly.
The energy of oscillation of the bead for an amplitude `y_(0)` is equal to (`x_(0)=`maximum displacement of the bead in the process of lowering)

Two light verticle springs 1 and 2 of stiffness K and 2K are connected by a 1 light horizontal rod. A bead of chewing gum of mass 'm' is placed gently at the mid point of the rod and lowered slowly. The period of SHM of the bead is

Two cubes of mass m_(1) and m_(2) are interconnected by a weightless spring of stiffness k and placed on a smooth horizontal table. Then the cubes are drawn closer to each other and released. Find the frequency of oscillation.

Two spring of spring constants k_(1) and k_(2) ar joined and are connected to a mass m as shown in the figure. Calculate the frequency of oscillation of mass m.

A bead of mass m is attached to the mid-point of a taut, weightless string of length l and placed on a frictionless horizontal table. Under a small transverse displacement x, as shown, if the tension in the string is T, then the frequency of oscillation is-

Two light vertical springs with equal natural length and spring constants k_(1) and k_(2) are separated by a distance l . Their upper end the ends A and B of a light horizontal rod AB . A vertical downwards force F is applied at point C on the rod. AB will remain horizontal in equilibrium if the distance AC is

two light identical springs of spring constant K are attached horizontally at the two ends of a uniform horizontal rod AB of length l and mass m. the rod is pivoted at its centre 'o' and can rotate freely in horizontal plane . The other ends of the two springs are fixed to rigid supportss as shown in figure . the rod is gently pushed through a small angle and released , the frequency of resulting oscillation is :

Springs of spring constant k, 2k, 4k , 8k, …. Are connected in series. A block of mass 50 kg is attached to the lower end of the last spring and the system is set into oscillation. If k = 3.0 N/cm, what is the time period of oscillations ?

A block of mass m is connected between two springs (constants K_(1) and K_(2) ) as shown in the figure and is made to oscillate, the frequency of oscillation of the system shall be-