A particle starts SHM from the mean position its amplitude is a and total energy E. At one instant is kinetic energy is `(3E)/(4)` . Its displacement at that instant is

A particle starts simple harmonic motion from the mean position. Its amplitude is a and total energy E . At one instant its kinetic energy is 3E/4 . Its displacement at that instant is

A particle stars SHM at time t=0. Its amplitude is A and angular frequency is omega. At time t=0 its kinetic energy is E/4 . Assuming potential energy to be zero and the particle can be written as (E=total mechanical energy of oscillation).

A particle starts simple harmonic motion from the mean position. Its amplitude is a and time period is T. what is its displacement when its speed is half of its maximum speed?

In SHM with amplitude a, the potential energy and kinetic energy are equal to each other as displacement

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:

The total energy of the body executing S.H.M. is E. Then the kinetic energy when the displacement is half of the amplitude is

A particle is released from a height S. At certain height its kinetic energy is three times its potential energy. The height and speed of the particle at that instant are respectively

The momentum of a body is p and its kinetic energy is E. Its momentum becomes 2p. Its kinetic energy will be

Calculate the ratio of displacement to amplitude when kinetic energy of a body is thrice its potential energy.

The total work done on a particle is equal to the change in its kinetic energy