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

In case of simple harmonic motion - (a) What fraction of total energy is kinetic and what fration is potential when displacement is one hall of the amplitude. (b) At what displacement the kinetic and potential energies are equal.

A particle executes SHM. (a) What fraction of total energy is kinetic and what fraction is potential when displacement is one half of the amplitude? (b) At what value of displacement are the kinetic and potential energies equal?

A particle excutes SHM, at what value of displacement are the kinetic and potential energies equal?

A particle executes simple harmonic motion with an amplitude of 10 cm. At what distance from the mean position are the kinetic and potential energies equal?

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

In case of simple harmonic motion – (A) What fraction of total energy is kinetic and what fraction is potential when displacement is one half of the amplitude.

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 executing simple harmonic motion. At a displacement x from mean position, its potential energy is E_(1)=2J and at a displacement y from mean position, its potential energy is E_(2)=8J . The potential energy E at a displacement (x+y) from mean position is