Graph shows the `x(t)` curves for the three experiments involving a particular spring block system oscillating in SHM. The kinetic energy of the system is maximum at `t=4` s. For the situation.

In S.H.M., the graph between kinetic energy K and time 't' is

Two blocks A and B each of mass m are connected by a massless spring of natural length L and spring constant k. The blocks are initially resting on a smooth horizontal floor with the spring at its natural length. A third identical block C also of mass m moves on the floor with a speed v along the line joining A and B and collides with A. Then The kinetic energy of the A-B system at maximum compression of the spring is mv^(2)//4 The maximum compression of the spring vsqrt(m//3k) The kinetic energy of the A-B system at maximum compression The maximum coppression of the spring is vsqrt(m//k)

While comparing the L-C oscillations with the oscillations of spring-block system, with whom the magnetic energy can be compared and why?

A body performs S.H.M. Its kinetic energy K varies with time t as indicated by graph

In S.H.M., potential energy (U) V/s, time (t) . Graph is

i.The acceleration versus time graph of a partical SHM is shown in the figure . Plot the displacement versus time graph ii. The frection of oscillation is…….. iii. The displacement amplitude is ……… iv. At t = 0 , the velocity of the partical is ...... v. The kinetic energy of the partical is maximum at t = ....... and t = ...... vi. The potential energy is maximum at t = ....... : t = ..... ans t = .........

For a particle executing S.H.M., the kinetic energy K is given K = K_(0) cos ^(2)omega t . The maximum value of potential energy is:

A block moves with a certain speed and collides with another identical block kept at rest . There is maximum possible loss of kinetic energy in this collision . Find the ratio initial kinetic energy of the sustem to that with final kinetic enegy of the system .

A constant external torque tau acts for a very brief period Delta t on a rotating system having moment of inertia I . ( i ) The angular momentum of the system will change by tau Delta t ( ii ) The angular velocity of the system will change by (tau Delta t)//I . ( iii ) If the system was initially at rest, it will acquire rotational kinetic energy (tau Delta t)^(2)//2I . ( iv ) The kinetic energy of the system will change by (tau Delta t)^(2) I .

A particle of mass 1 kg is hanging from a spring of force constant 100 Nm^(1) . The mass is pulled slightly downward and released so that it executes free simple harmonic motion with time period T. The time when the kinetic energy and potential energy of the system will become equal, is (T)/(x) The value of x is_______