If two sources have a randomly varying phase difference f(t), the resultant intensity will be given by:

Assertion: Two identical waves due to two coherent sources interfere at a point with a phase difference of (2pi)/3 , then the resultant intensity at this point is equal to the individual intensity of the sources. Reason: A phase difference of (2pi)/3 is equivalent to a path difference of lambda/3 .

When two waves of intensities l_1 and l_2 coming from coherent sources interfere at a point P, where phase difference is phi , then resultant intensity (l_(res)) at point P would be

Waves of same amplitude and same frequency from two coherent source overlap at a point. The ratio of the resultant intensity when they arrive in phase to that when they arrive with 90^(@) phase difference is

Two sound waves having a phase difference of 60^(@) have path difference of

Two waves having intensity I and 9I produce interference . If the resultant intensity at a point is 7 I , what is the phase difference between the two waves ?

It is found that what waves of same intensity from two coherent sources superpose at a certain point, then the resultant intensity is equal to the intensity of one wave only. This means that the phase difference between the two waves at that point is

Two incoherent sources of intensities l and 4l superpose then the resultant intensity is

Four sources of sound each of sound level 10 dB are sounded together in phase , the resultant intensity level will be (log _(10) 2 = 0.3)

In Young's double slit experiment two disturbances arriving at a point P have phase difference fo (pi)/(3) . The intensity of this point expressed as a fraction of maximum intensity I_(0) is

Two light sources with intensity I_(0) each interfere in a medium where phase difference between them us (pi)/2 . Resultant intensity at the point would be.