On the superposition of two waves `[y_1 = 3 sin (50 pi t - 20x)]` and `[y_2 = 3sin (50pi t -20 x +(pi/3)]`the equation resultant wave will be

Determine the resultant of two waves given by y_(1) = 4 sin(200 pi t) and y_(2) = 3 sin(200 pi t + pi//2) .

Standing waves are produced by superposition of two waves y_(1) = 0.05 sin(3pi t - 2x), y_(2) = 0.05 six(3pi t +2x) where x and y are measured in metre and t in second. Find the amplitude of the particle at x = 0.5m.

The displacement at a point due to two waves are y_1=4 sin (500pit) and y_2=2sin(506 pi t) . The result due to their superposition will be

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

10 beats/ are produced by the superposition of two sound waves. If the equation of the first wave is y_(1) = 5 sin 20 pi (30t) , then the equation of second wave is

The equations of two sound waves are given by, y_1 = 3sin ( 100 pi t ) and y_2 =4sin ( 150 pi t ) , The ratio of intensites of sound produced in the medium is

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

If two sound waves, y_(1) = 0.3 sin 596 pi[t - x//300] and y_(2) = 0.5 sin 604 pi [t - x//330] are superimposed, what will be the (a) frequencyof resultant wave

The displacements of two interfering light waves are y_(1) = 2sin omega t and y_(2) = 5sin (omega t+(pi)/(3)) the resultant amptitude 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?