From differential equation of linear S.H.M obtain an expression for acceleration. Velocity and displacement of a particle performing S.H.M.
A sononmeter wire 1 meter long weighing 2 g is in resonsnace with a tunning fork of frequency 300 Hz. Find tension in the sonometer wire.

A stretched wire of length 1 m and weighing 1 gram is in unison with a tuning fork of frequency 200 Hz. The tension in the wire will be

The graph between instantaneous acceleration and angualr displacement of a particle performing S.H.M. is

The graph between instantaneous velocity and angular displacement of a particle performing S.H.M. is

The graph between instantaneous velocity and acceleration of a particle performing S.H.M. is

The graph between instantaneous velocity and displacement of a particle performing S.H.M.with period 2pi sec or omega = 1 is

The phase difference between displacement and acceleration of a particle performing S.H.M. is

The ratio of maximum acceleration to the maximum velocity of a particle performing S.H.M. is equal to

State of differential equation equation of linear simple harmonic motion. Hence obtain the expression for acceleration, velocity and displacement of a particle performing linear S.H.M. A body cools from 80^(@)C to 70^(@)C in 5 minutes and to 62^(@)C in the next 5 minutes. Calculate the temperature of the surroundings.

Write the relation between acceleration, displacement and frequency of a particle executing S.H.M.

The graph between instantaneous velocity and acceleration of a particle performing S.H.M. with a period of 6.28 s is