Two waves are represented by the equations
`y_(1)=asin(omegat+kx+0.57)m` and
`y_(2)=acos(omegat+kx)`m,
where x is in metres and t is in seconds. The phase difference between them is

Two waves are represented by the equations y_1=asin(omegat=kx+0.57)m and y_2=acos(omegat+kx) m where x is in metre and t in second. The phase difference between them 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

Two waves are represented by the equations y_1=a sin omega t and y_2=a cos omegat . The first wave

The displacements of two travelling waves are represented by the equations as : y_(1) = a sin (omega t + kx + 0.29)m and y_(2) = a cos (omega t + kx)m here x, a are in m and t in s, omega in rad. The path difference between two waves is (x xx 1.28) (lambda)/(pi) . Find the value of x.

The two waves are represented by y_(1) 10^(-6) sin(100t (x)/(50) 0.5)m Y_(2) 10^(-2) cos(100t (x)/(50))m where x is ihn metres and t in seconds. The phase difference between the waves is approximately:

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 -

Two waves are represented by y_(1)=a_(1)cos (omega t - kx) and y_(2)=a_(2)sin (omega t - kx + pi//3) Then the phase difference between them is-