`y_1`=4sin(`omega`t + kx), y2 = -4 cos(`omega`t + kx), the phase difference is

Two SHM's are represented by y = a sin (omegat - kx) and y = b cos (omegat - kx) . The phase difference between the two is :

Two waves are given by y_(1) = a sin (omega t - kx) and y_(2) = a cos (omega t - kx) . The phase difference between the two waves is

Two SHMs are respectively represented by y_(1)=a sin (omegat-kx) and y_(2)=b cos(omegat-kx) . The phase difference between the two is

Two waves are given by y_(1)=asin(omegat-kx) and y_(2)=a cos(omegat-kx) . The phase difference between the two waves is -

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 simple harmonic motions are represented by y_(1)= 10 "sin" omega t " and " y_(2) =15 "cos" 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

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

The instantaneous values of current and voltage in an A.C. circuit are respectively I = 4 sin omega t and E = 100 cos ( Omega t + pi //3) . The phase difference between voltage and current is

The instantaneous values of current and voltage in an A.C. circuit are respectively I = 4 sin omega t and E= 100 cos( omega t+ pi//6) . The phase difference voltage and current is