Four simple harmonic vibrations
`y_(1)=8 sin omega t`, `y_(2)= 6 sin (omega t+pi//2)`, `y_(3)=4 sin (omega t+pi)`, `y_(4)=2sin(omegat+3pi//2)`
are susperimposed on each other. The resulting amplitude and phase are respectively.

For simple harmonic vibrations y_(1)=8cos omegat y_(2)=4 cos (omegat+(pi)/(2)) y_(3)=2cos (omegat+pi) y_(4)=cos(omegat+(3pi)/(2)) are superimposed on one another. The resulting amplitude and phase are respectively

Four simple harmonic vibrations x_(1) = 8sinepsilont , x_(2) = 6sin(epsilont+pi/2) , x_(3)=4sin(epsilont+pi) and x_(4) = 2sin(epsilont+(3pi)/2) are superimposed on each other. The resulting amplitude and its phase difference with x_(1) are respectively.

If i_(1)=3 sin omega t and (i_2) = 4 cos omega t, then (i_3) is

Two simple harmonic motions are given by y _(1) = 5 sin ( omegat- pi //3). y_(2) = 5 ( sin omegat+ sqrt(3) cos omegat) . Ratio of their amplitudes is

Four waves are expressed as 1. y_1=a_1 sin omega t 2. y_2=a_2 sin2 omega t 3. y_3=a_3 cos omega t 4. y_4=a_4 sin (omega t+phi) The interference is possible between

Four sound sources produce the following four waves (i) y_(1)=a sin (omega t+phi_(1)) (ii) y_(2)=a sin 2 omega t (iii) y_(3)= a' sin (omega t+phi_(2)) (iv) y_(4)=a' sin (3 omega t+phi) Superposition of which two waves gives rise to interference?

x_(1) = 5 sin omega t x_(2) = 5 sin (omega t + 53^(@)) x_(3) = - 10 cos omega t Find amplitude of resultant SHM.

x_(1) = 5 sin omega t x_(2) = 5 sin (omega t + 53^(@)) x_(3) = - 10 cos omega t Find amplitude of resultant SHM.

When two displacement represented by y_(1) = a sin (omega t) and y_(2) = b cos (omega t) are superimposed, the motion is

Two particle A and B execute simple harmonic motion according to the equation y_(1) = 3 sin omega t and y_(2) = 4 sin [omega t + (pi//2)] + 3 sin omega t . Find the phase difference between them.