The angualr displacement of an object having uniform cirular motion is ` pi/4` rad in every 3s. Find its frequency of revolution.

If the displacement of an object during its motion is 100 m in a time interval of 20 s, then calculate the average velocity of the object with which it was moving through out his journey.

A particle goes uniformly in circular motion with an angualr speed pi/8 rad s^(-1) . What is its time period ?

A particle is executing SHM given by x = A sin (pit + phi) . The initial displacement of particle is 1 cm and its initial velocity is pi cm//sec . Find the amplitude of motion and initial phase of the particle.

Assertion : The total displacement moved by a point located on the periphery of a wheel of radius R in one revolution is 2 pi R. Wheel is rolling. Reason : In rolling motion of a wheel, every point on its periphery comes in contact with the surface once in one revolution.

The displacement x (in metre ) of a particle in, simple harmonic motion is related to time t ( in second ) as x= 0.01 cos (pi t + pi /4) the frequency of the motion will be

The displacement of a particel moving with uniform acceleration after r's given by s = 10 t + 4.9 t ^2 ? What is the magnitude the final velocity at t = 3 s and the uniform acceleration .

A particle executing simple harmonic motion of amplitude 5 cm has maximum speed of 31.4 cm / s . The frequency of its oscillation is

The displacement (s)- velocity ( v ) graph of a particle if it starts moving from rest with a uniform acceleration which is parallel to its instantaneous direction of motion is

A particle executes simple harmonic motion about the point x=0 . At time t=0 , it has displacement x=2cm and zero velocity. If the frequency of motion is 0.25 s^(-1) , find (a) the period, (b) angular frequency, ( c) the amplitude, (d) maximum speed, (e) the displacement from the mean position at t=3 s and (f) the velocity at t=3 s .

An object of mass 0.8kg is attached to one end of a spring and the system is set into simple harmonic motion. The displacement x of the object as a fuction of time is shown in the figure. With the aid of the data, determine (a) the amplitude A of the motion, (b) the angular frequency omega , ( c) the spring constant K , (d) the speed of the object at t = 1.0 s and (e) the magnitude of the object's acceleration at t = 1.0 s .