Find the angular frequency and the amplitude of harmonic oscillations of a particle if at distances `x_(1)` and `x_(2)` from the equalibrium position its velocity equald `v_(1)` and `v_(2)` respectively.

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 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 executing harmonic motion is having velocities v_1 and v_2 at distances is x_1 and x_2 from the equilibrium position. The amplitude of the motion is

The frequency of oscillation of a particle executing SHM with amplitude A and having velocity 'v' at the mean position is

Amplitude of a harmonic oscillator is A, when velocity of particle is half of maximum velocity, then determine position of particle.

The equation of a simple harmonic oscillator with amplitude 5 cm and period 2 sec is if particle is starting from the mean positions is–

A particle is performing harmonic motion if its velocity are v_(1) and v_(2) at the displecement from the mean position are y_(1) and y_(2) respectively then 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) The motion of the particle in simple harmonic motion is given by x = a sin omega t . If its speed is u , when the displacement is x_(1) and speed is v , when the displacement is x_(2) , show that the amplitude of the motion is A = [(v^(2)x_(1)^(2) - u^(2)x_(2)^(2))/(v^(2) - u^(2))]^(1//2) (b) A particle is moving with simple harmonic motion is a straight line. When the distance of the particle from the equilibrium position has the values x_(1) and x_(2) the corresponding values of velocity are u_(1) and u_(2) , show that the period is T = 2pi[(x_(2)^(2) - x_(1)^(2))/(u_(1)^(2) - u_(2)^(2))]^(1//2)

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