If two sound waves:
`y_1=0.3"sin"596 pi(t-x/330)"and" y_2=0.5"sin"604pi(t-x/330)` are superposed.
What will be (i) the frequency of the resultant wave (ii) the frequency at which the amplitant wave varies?

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

The equation of the progressive wave is y = 5 sinpi//2(100t-x) cm. The frequeny of the wave is---

Two progressive waves y_(1) = 4 sin 500 pi t and y _(2) = 2 sin 506 pi t are superposed. Find the number of beats produced in one minute .

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

Equations of two light waves are y_(1) = 4 sin omega t and y_(2) = 3 sin (omega t + (pi)/(2)) . What is the amplitude of the resultant wave as they superpose on each other?

When two waves y_(1) A sin 2000 pi t and y_(2) = A sin 2008 pi t are superposed, the number of beats produced per second is

Two waves represented as y_(1) = A_(1) sin omega t and y_(2) = A_(2) cos omega t superpose at a point in space. Find out the amplitude of the resultant wave at that point .

When the waves y_(1) = A sin omega t and y_(2) = A cos omega t are superposed, then resultant amplitude will be

The equations of two sound waves are given below : y_(1) = 0 . 2 "sin" (2pi)/(3) (330 t - x) m and y_(2) = 0 .02 "sin" (2pi)/(3 + k) (330 t - x) m If 10 beats are produced per sound due to superposition of these two waves, determine the value of k .