Two coherent sources `S_(1)" and "S_(2)` are separated by a small distance d. The fringes obtained on the screen will be:

Two coherent point sources S_1 and S_2 are separated by a small distance d as shown. The fringes obtained on the screen will be

Two coherent point sources S_1 and S_2 are separated by a small distance d as shown. The fringes obtained on the screen will be

Two coherent sources S_1 and S_2 area separated by a distance four times the wavelength lambda of the source. The sources lie along y axis whereas a detector moves along +x axis. Leaving the origin and far off points the number of points where maxima are observed is

Two monochromatic coherent point sources S_(1) and S_(2) are separated by a distance L. Each sources emits light of wavelength lambda , where L gt gt lambda . The line S_(1) S_(2) when extended meets a screen perpendicular to it at point A. Then

Consider two coherent, monochromatic (wavelength lambda ) sources S_(1) and S_(2) , separated by a distance d. The ratio of intensities of S_(1) and that of S_(2) (which is responsible for interference at point P, where detector is located) is 4. The distance of point P from S_(1) is (if the resultant intensity at point P is equal to (9)/(4) times of intensity of S_(1) ) ("Given : "angleS_(2)S_(1)P=90^(@), d gt0 and n" is a positive integer")

In Young's doulbe-slit experiment the separation between two coherent sources S_(1) and S_(2) is d and the distance between the source and screen is D. In the interference pattern, it is found that exactly in front of one slit, there occurs a minimum. Then the possible wavelengths used in the experiment are

There is a large circle (not a screen this time) around two coherent sources S_1 and S_2 kept at a distance d = 3.4 lambda . (a) Find total number of maximas on this circle. (b) Four angular positions corresponding to third order maxima on this circle.

Two coherent source of light can be obtained by

Statement I: Two point coherent sources of light S_(1) and S_(2) are placed on a line as shown in figure. P and Q are two points on that line. If at point P maximum intensity is observed, then maximum intensity should also be observed at Q. Statement II: In figure the distance |S_(1) P - S_(2) P| is equal to distance |S_(1) Q - S_(2) Q| .

Figure shows two line sources of sound, S_1 and S_2 separated by a distance 4 m.The two sources are in same phase at all times.The source emit same power and their lengths are also same.A detector moves along a circle with center at S_2 and radius 3m. The wavelength of the sound is 1m.When it is at A the intensity of sound due to source S_2 only is I_0 . The intensity o sound of B due to S_1 and S_2 is :