A particle is executing S.H.M. If`u_(1)` and `u_(2)` are the velocitiesof the particle at distances`x_(1)` and`x_(2)` from the mean position respectively, then

A particle is executing SHM if u_(1) and u_(2) are the speeds of the particle at distances x_(1) and x_(2) from the equilibrium position, shown that the frequency of oscillation f=(1)/(2pi)((u_(1)^(2)-u_(2)^(2))/(x_(2)^(2)-x_(1)^(2)))

A particle is executing SHM along a straight line. Its velocities at distances x_(1) and x_(2) from the mean position are v_(1) and v_(2) , respectively. Its time period is

A particle is executing a linear S.H.M. v_(1) " and " v_(2) are as speeds at dis"tan"ces x_(1) " and " x_(2) from the equilibrium position. What is its ampiltude of oscillation ?

A particle executing linear S.H.M. has velocities v_(1) and v_(2) at distances x_(1) and x_(2) respectively from the mean position. The angular velocity of the particle is

The equation of motion of a particle executing S.H.M. is a = - bx , where a is the acceleration of the particle, x is the displacement from the mean position and b is a constant. What is the time period of the particle ?

The amplitude of a particle executing SHM is 4 cm. At the mean position, the speed of the particle is 16 cm/s. The distance of the particle from the mean position at which the speed of the particle becomes 8sqrt(3) cm/sec will be

The total energy of a particle executing S.H.M. is 80 J . What is the potential energy when the particle is at a distance of 3/4 of amplitude from the mean position

Velocity at mean position of a particle executing S.H.M. is v , they velocity of the particle at a distance equal to half of the amplitude

A particle executing linear SHM has velocities v_(1) " and " v_(2) at dis"tan"ce x_(1) " and " x_(2) , respectively from the mean position. The angular velocity of the particle is