A body is executing simple harmonic motion. At a displacement x, its potential energy is `E_1` and a displacement y, its potential energy is `E_2`. The potential energy E at a displacement (x+y) is

A body executes simple harmonic motion. At a displacement x, its potential energy is U_1 . At a displacement y, its potential energy is U_2 . What is the potential energy of the body at a displacement (x + y)?

A body is executing simple harmonic motion. At a displacement x (from its mean position) its potential energy is E_(1) and at a displacement y its potential energy is E_(2) . The potential energy is E at displacement (x+y) . Then:

A body is performing SHM At a displacement X_1 , its potential energy is 4 J and at a displacement X_2 , its potential energy is 9 J. The potential energy at a displacement (X_1 + X_2) is

A particle is executing simple harmonic motion. Its total energy is proportional to its

In a simple harmonic motion, when the displacement is one-half the amplitude, what fraction of the total energy is kinetic ?

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 executing SHM with an amplitude A. The displacement of the particle when its potential energy is half of its total energy is

At what displacement the kinetic is equal to the potential energy ?

In simple harmonic motion of a particle, maximum kinetic energy is 40 J and maximum potential energy is 60 J. then

For a particle executing simple harmonic motion, the displacement x is given by x= Acosomegat . Identify the graph, which represents the variation of potential energy (U) as a function of time t and displacement x.