`x = A cos omega t + B sin omega t`, the amplitude of this wire is:

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

Two simple harmonic motions are given by x_(1) = a sin omega t + a cos omega t and x_(2) = a sin omega t + (a)/(sqrt3) cos omega t The ratio of the amplitudes of first and second motion and the phase difference between them are respectively

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 .

The equations for displacement of two light waves forming interference pattern are y_(1) = 4 sin omega t and y_(2) =3 sin (omega t+ (pi)/(2)) . Determine the amplitude of the resultant wave.

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?

The equation of a stationary wave is y = 2 A sin k x cos omega t . Find the amplitudes, velocities and wavelengths of the two progressive waves, which on superposition produce this stationary wave .

The equation of an SHM is x=8 sin omega t + 15 cos omega t , where x is displacement and t is time . The amplitude will be