When two progressive waves `y_(1) = 4 sin (2x - 6t)` and `y_(2) = 3 sin (2x - 6t - (pi)/(2))` are superimposed, the amplitude of the resultant wave is

Two progressive waves having equation x_(1) = 3 sin omegatau and x_(2) = 4 sin (omegatau + 90^(@)) are superimposed. The amplitude of the resultant wave is

two waves y_1 = 10sin(omegat - Kx) m and y_2 = 5sin(omegat - Kx + π/3) m are superimposed. the amplitude of resultant wave is

The displacement of the interfaring light waves are y_1 =4 sin omega t and y_2=3sin (omegat +(pi)/( 2)) What is the amplitude of the resultant wave?

If two waves represented by y_(1)=4 sin omega t and y_(2)=3sin (omega t+(pi)/(3)) interfere at a point, the amplitude of the resulting wave will be about

Two waves are passing through a region in the same direction at the same time . If the equation of these waves are y_(1) = a sin ( 2pi)/(lambda)( v t - x) and y_(2) = b sin ( 2pi)/( lambda) [( vt - x) + x_(0) ] then the amplitude of the resulting wave for x_(0) = (lambda//2) is

Two waves represented by y=a" "sin(omegat-kx) and y=a" " sin(omega-kx+(2pi)/(3)) are superposed. What will be the amplitude of the resultant wave?

The waves produced by two sources of sound are given by y_(1) = 10 sin (200 pi t) and y_(2) = 10 sin (210 pi t) . If the waves superimpose, then the no. of beats heard by the listener in one minute will be

The displacements of two intering lightwaves are y_(1) = 4 sin omega t and y_(2) = 3 cos(omega t) . The amplitude of the resultant wave is ( y_(1) and y_(2) are in CGS system)