Assertion: In a simple harmonic motion the kinetic and potential energy becomes equal when the displacement is `(1)/(sqrt(2))` time the amplitude
Reason: is `SHM` kinetic energy is zero when potential energy is maximum

Kinetic Energy|Potential Energy

The ratio of the kinetic to potential energy of a particle in SHM, when its displacement is one-half the amplitude, is

For simple Harmonic Oscillator, the potential energy is equal to kinetic energy

In case of simple harmonic motion – (B) At what displacement the kinetic and potential energies are equal.

In a simple harmonic motion (i) the maximum potential energy equal the maximum kinetic energy (ii) the minimum potential energy equals the minimum kinetic energy (iii) the minimum potential energy equals the maximum kinetic energy (iv) the maximum potential energy equals the minimum kinetic energy

A body is executing a simple harmonic motion such that its potential energy is U_(1) at U_(2)at y When the displacement is x+y the potential energy will be

A particle is performing linear SHM, along x-axis when the displacement becomes, (A)/(sqrt2) , (A is the amplitude), the relation that holds between kinetic energy and potential energy is ……..

If a body is executing simple harmonic motion and its current displacement is (sqrt(3))/(2) times the amplitude from its mean position, then the ratio between potential energy and kinetic energy is

A particle executes simple harmonic motion along a straight line with an amplitude A . The potential energy is maximum when the displacement is