Two sinusoidal waves are superposed. Their equations are
`y_(1)=Asin(kx-omegat+(pi)/(6))and y_(2)=Asin(kx-omegat-(pi)/(6))`
the equation of their resultant is

Two parallel S.H.M.s have equations y_1=A_1sin(omegat+2pi) and y_2=A_2sin(omega/t+4pi) . The amplitude of the resultant motion is

Two particle are executing SHMs .The equations of their motions are y_(1)=10"sin"(omegat+(pi)/(4)) " and "y_(2)=5 "sin"(omegat+(sqrt(3)pi)/(4)) What is the ratio of their amplitudes.

y(xt)=asin(kx-omegat+phi) represents a

Three travelling waves are superimposed. The equations of the wave are y_(!)=A_(0) sin (kx-omegat), y_(2)=3 sqrt(2) A_(0) sin (kx-omegat+phi) and y_(3)=4 A_(0) cos (kx-omegat) find the value of phi ("given "0 le phi le pi//2) if the phase difference between the resultant wave and first wave is pi//4

Two simple harmonic motions A and B are given respectively by the following equations. y_(1)=asin[omegat+(pi)/(6)] y_(2)=asin[omegat+(3pi)/(6)] Phase difference between the waves is

If a waveform has the equation y_1=A_1 sin (omegat-kx) & y_2=A_2 cos (omegat-kx) , find the equation of the resulting wave on superposition.

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

The displacement of two interfering light waves are given by y_(1)=3 sinomegat,y_(2)=4 sin(omegat+pi//2) . The amplitude of the resultant wave is

Two longitudinal waves propagating in the X and Y directions superimpose. The wave equations are as below Phi_(1)=A(omegat-kx) and Phi_(2)=Acos(omegat-ky) . Trajectory of the motion of a particle lying on the line y=x((2n+1)lamda)/(2) will be