Assume `x_1 = A Sin(omega t)` and `x_2 = A Cos (omega t + π/6)`. The phase difference between `x_1` and `x_2` is

Two SHM are represented by equations x_1=4sin(omega t+37°) and x_2=5cos(omega t) . The phase difference between them is

Equations of a stationary and a travelling waves are as follows y_(1) = sin kx cos omega t and y_(2) = a sin ( omega t - kx) . The phase difference between two points x_(1) = pi//3k and x_(2) = 3 pi// 2k is phi_(1) in the standing wave (y_(1)) and is phi_(2) in the travelling wave (y_(2)) then ratio phi_(1)//phi_(2) is

if x = a sin (omegat + pi//6) and x' = a cos omega , t, then what is the phase difference between the two waves

If i_(1)=3 sin omega t and (i_2) = 4 cos omega t, then (i_3) is

Two particle A and B execute simple harmonic motion according to the equation y_(1) = 3 sin omega t and y_(2) = 4 sin [omega t + (pi//2)] + 3 sin omega t . Find the phase difference between them.

x=x_(1)+x_(2) (where x_(1)=4 cos omega t and x_(2)=3 sin omega t ) is the equation of motion of a particle along x-axis. The phase different between x_(1) and x is

Two waves are represented by the equations y_(1)=a sin (omega t+kx+0.785) and y_(2)=a cos (omega t+kx) where, x is in meter and t in second The phase difference between them and resultant amplitude due to their superposition are

A particle is subjected to SHM as given by equations x_1 = A_1 sin omegat and x_2 = A_2 sin (omega t + pi//3) .The maximum acceleration and amplitude of the resultant motion are it a_("max") and A ,respectively , then

A x and y co-ordinates of a particle are x=A sin (omega t) and y = A sin(omegat + pi//2) . Then, the motion of the particle is

A partical is subjucted to two simple harmonic motions x_(1) = A_(1) sin omega t and x_(2) = A_(2) sin (omega t + pi//3) Find(a) the displacement at t = 0 , (b) the maximum speed of the partical and ( c) the maximum acceleration of the partical.