If angular frequency of simple harmonic oscillator is `2` rad/s, then the graph between velocity and displacement is

In a simple harmonic oscillator, at the mean position

The total energy of a simple harmonic oscillation is proportional to

The position and velocity of a particle executing simple harmonic motion at t = 0 are given by 3 cm and 8 cm s^(-1) respectively . If the angular frequency of the particle is 2 "rad s" ^(-1) , then the amplitude of oscillation (in cm) is

If the frequency of the acceleration of a simple harmonic oscillator if f_0 then the frequency of the potwntial energy is

In damped oscillation graph between velocity and position will be : -

The graph showing the variation of K.E. or P.E. with displacement of a harmonic oscillator is a parabola, but that of total energy with displacement is a straight line. Why?

Passage V) In SHM displacement, velocity and acceleration all oscillate simple harmonically with same angular frequency omega . Phase difference between any two is pi/2 except that between displacement and acceleration which is pi . v-t graph of a particle is SHM is as shown in figure Choose the wrong option.

If x is the displacement of a simple harmonic oscillator at a certain instant and y its acceleration at that instant, draw graph of (x, y) at all instant in one complete oscillation,

If amplitude of velocity is V_0 then the velocity of simple harmonic oscillator at half of the amplitude is

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