Two waves represented by the following equations are travelling in the same ` y_1 = 5 sin 2pi ( 75 t - 0.25x ) y_2 10 sin 2pi ( 150 t - 0.50x ) .` The intensity ratio ` I_1//I_2 `of the two waves is

Two waves are represented by the following equations y_(1) = 5 sin 2pi (10t -0.1 x) y_(2) = 10 sin 2pi (20t - 0.2 x) Ratio of intensites I_(2)//I_(1) will be

Two superimposig waves are represented by equation y_1=2 sin 2 pi ( 10t-0.4x) and y_2=4 sin2 pi ( 20 t- 0.8x) . The ratio of l_("max") " to " l_("min") is

Following is given the equation of a travelling wave (all is SI unit) y = (0.02) sin 2pi (10t - 5x) Match of following.

A wave is given by the equation y = 10 sin 2 pi (100 t - 0.02 x) + 10 sin 2 pi (100 t + 0.02 x) Find the loop length , frequency , velocity and maximum amplitude of the stationary wave produced.

A wave is given by the equation y = 10 sin 2 pi (100 t - 0.02 x) + 10 sin 2 pi (100 t + 0.02 x) Find the loop length , frequency , velocity and maximum amplitude of the stationary wave produced.

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

Two mechanical waves, y_(1) = 2 sin 2 pi (5- t - 2x) & y_(2) = 4 sin 2 pi(fax + 100 t) propagate in a medium with same speed.

A wave is represented by the equation y=(0.001mm)sin[(50s^-1t+(2.0m^-1)x]

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 SHMs are represented by equations y_1 = 4 sin[3 pi t + ( pi /3)], y_2 = 4 [sin(3 pi t) + sqrt 3 cos (3 pi t)], then the ratio of their amplitudes is