In case of mechanical wave a particle oscillates and during oscillation its kinetic energy and potential energy changes.

The magnitude of acceleration of a simple harmnic oscillator when its kinetic energy and potential energy are same, if amplitude of acceleration is a_0 is

The total work done on a particle is equal to the change in its kinetic energy

The total work done on a particle is equal to the change in its kinetic energy

In position A kinetic energy of a particle is 60 J and potential energy is -20 J. In position B, kinetic energy is 100 J and potential energy is 40 J. Then, in moving the particle from A to B

In case of damped oscillation frequency of oscillation is

Assertion: y-x graph of a transverse wave on a string is as shown in figure. At point A potential energy and kinetic energy both are minimum. Reason : At point B kinetic energy and potential energy both are maximum.

A loaded vertical spring executes simple harmonic oscillations with period of 4 s. The difference between the kinetic energy and potential energy of this system oscillates with a period of

A particle starts oscillating simple harmonically from its equilibrium position then, the ratio of kinetic energy and potential energy of the particle at the time T//12 is: (T="time period")

When a particle executes SHM oscillates with a frequency v, then the kinetic energy of the particle

When a particle oscillates in simple harmonic motion, both in potential energy and kinetic energy vary sinusoidally with time. If v be the frequency of the motion of the particle, the frequency associated with the kinetic energy is :