A body is executing siniple Harmonic Motion . At displament its potenial energy is `E_(1)` and at a displacement y its potenial energy is `E_(2) ` . The potenial energy E at displament `(x+)` is

A body is executing simple harmonic motion As x displacement x its potential energy is E_(1) and at a displacement y its potential energy is E_(2) The potential energy E at displacement (x+y) is

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 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 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 particle is executing SHM. At a displacement y_(1) its potential energy is U_(1) and at a displacement y_(2) its potential energy is U_(2) . The potential energy of the particle at displacement (y_(1)+y_(2)) is

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 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 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

A body is executing simple harmonic motion with frequency 'n' the frequency of its potential energy is