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

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

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

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

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

If I_1/I_2 =4 then find the value of (I_max - I_min)/ (I_max+I_min)

If I_1/I_2 =16 then find the value of (I_max - I_min)/ (I_max+I_min)

If I_1/I_2 =25 then find the value of (I_max - I_min)/ (I_max+I_min)

If I_1/I_2 =9 then find the value of (I_max - I_min)/ (I_max+I_min) A ̅

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

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