For Question `x= A cos ( omega t + phi)` ,find (i) period and (ii) initial phase

For Question x= 0.25 cos ( 6000 t + 0.85) ,find (i) period and (ii) initial phase

The motion of a particle in S.H.M. is described by the displacement function, x=Acos(omegat+phi) , If the initial (t=0) position of the particle is 1cm and its initial velocity is omega cm s^(-1) , what are its amplitude and initial phase angle ? The angular frequency of the particle is pis^(-1) . If instead of the cosine function, we choose the sine function to describe the SHM : x=B sin(omegat+alpha) , what are the amplitude and initial phase of the particle with the above initial conditions ?

x_(1) = 3 sin omega t implies x_(2) = 4 cos omega t . Find (i) amplitude of resultant SHm, (ii) equation of the resultant SHm.

x_(1) = 3 sin omega t , x_(2) = 4 cos omega t . Find (i) amplitude of resultant SHM, (ii) equation of the resultant SHM.

x_(1) = 3 sin omega t , x_(2) = 4 cos omega t Find (i) amplitude of resultant SHM, (ii) equation of the resultant SHM.

A simple harmonic oscillation is represented by the equation y = 0.5sin(50pi t+1.8) . Where y is in meter and t is in second. Find its amplitude, frequency, time period and initial phase.

Harmonic vibrations comply to the law s=0.20cos(300t+2) Find the amplitude, the frequency, the period and the initial phase of the vibrations.

A wave is travelling along x-axis . The disturbance at x=0 and t=0 is A/2 and is increasing , where A is amplitude of the wave. If Y= sin (kx-omegat+phi) , then the initial phase is alpha pi . Find alpha

Let the two waves y_(1) = A sin ( kx - omega t) and y_(2) = A sin ( kx + omega t) from a standing wave on a string . Now if an additional phase difference of phi is created between two waves , then

The displacement xi in centimetres of a particle is xi = 3 sin 314 t + 4 cos 314 t . Amplitude and initial phase are