The interference pattern is obtained with two coherent light sources of intensity ration n. In the interference pattern, the ratio
`(I_(max)-I_(min))/(I_(max)+I_(min))` will be

The interference pattern is obtained with two coherent light sources of intensity ratio n. In the interference patten, the ratio (I_(max)-I_(min))/(I_(max)+I_(min)) will be

Interference pattern is obtained with two coherent light sources of intensity ratio .b.. In the interference pattern, the ratio of (I_("max")-I_("min"))/(I_("max")+I_("min")) will be

Two coherent sources of intensity ratio alpha interfere in interference pattern (I_(max)-I_(min))/(I_(max)+I_(min)) is equal to

Two coherent sources of intensity ratio beta^2 interfere. Then, the value of (I_(max)- I_(min))//(I_(max)+I_(min)) is

The two coherent sources with intensity ratio beta produce interference. The fringe visibility will be

Two coherent sources of light of intensity ratio beta produce interference pattern. Prove that in the interferencepattern (I_(max) - I_(min))/(I_(max) + (I_(min))) = (2 sqrt beta)/(1 + beta) where I_(max) and I_(min) are maximum and mininum intensities in the resultant wave.

If the ratio of the intensity of two coherent sources is 4 then the visibility [(I_(max)-I_(min))//(I_(max)+I_(min))] of the fringes is

Two coherent sources of intensities I_1 and I_2 produce an interference pattern. The maximum intensity in the interference pattern will be

As a result of interference of two coherent sources of light, energy is

Two slits in Youngs experiment have widths in the ratio 1: 25.h The ratio of intensity at the macxima and minima in the interderence pattern I_(max)/(I_(min))is is