Two coherent narrow slits emitting sound of wavelength `lambda` in the same phase are placed parallet to each other at a small separation of `2 lambda` . The sound is delected by maving a delector on the screen at a distance `D(gt gt lambda)` from the slit `S_(1)` as shows in figure. Find the distance `y` such that the intensity at `P` is equal to intensity at `O` .

Two coherent narrow slits emitting light of wavelength lambda in the same phase are placed parallel to each other at a small separation of 2lambda . The light is collected on a screen S which is placed at a distance D(gtgt lambda ) from the slit S_1 as shown in figure. Find the finite distance x such that the intensity at P is equal to intensity O. .

A narrow slit S transmitting light of wavelength 'lambda' . Is placed at a distance d above a large plane mirror as shown. The light coming directly from the slit and that coming after the reflection interfere at a screen S placed at a distance D from the slit. at what distance from point O, the resultant intensity is maximum ? (there is a phase change of pi of reflection from the mirror)

In a Lloyds's mirror experiment as narrow slit S transmitting a light of wavelength lambda is placed 3 mm above a small plane mirror ( as shown). The light coming directly from the the slit and that coming after the reflection interfere on a screen placed at a distance of 90 cm from the slit. Length of mirror is 2 mm and the middle point of mirror is 2 mm from point P. If the mirror is shifted towards left then how does the fringe pattern on screen changes ?

Two coherent point sources S_1 " and "S_2 vibrating in phase light of wavelength lambda . The separation between them is 2lambda as shown in figure. The first bright fringe is formed at .P. due to interference on a screen placed at a distance .D. from S_(1)" "(D gt gt lambda) , then OP is

The figure shows two points source which emit light of wavelength lambda in phase with each other and are at a distance d = 5.5 lambda apart along a line which is perpendicular to a large screen at a distance L from the centre of the source. Assume that d is much less than L. Which of the following statement is (are) correct ?

A narrow slit S transmitting light of wavelength lamda is placed a distance d above a large plane mirror as shown in figure. The light coming directly from the slit and that coming after the reflection interference at a screen sum placed at a distance LD from the slit. a. What will be the intensity at a point just above the mirror. i.e., just above O? b. At what distance from O does the first maximum occur? ?

2 loudspeakers are emitting sound waves of wavelength lambda with an initial phase difference of pi/2 at what minimum distance from O on line AB will one hear a maximum

In a young's doule slits experiment, a monochromatic source of wavelength lambda is used to illuminate the two slits S_(1) and S_(2) . The slitss S_(1) and S_(2) are identical and source S is placed symmetrically as shown. interference pattern is observed on a screen at a distance D from the centre of slit. The distance between the slits is d. If the resultant intensity at P is same as that O, then the distance OP can not be

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")

A coherent parallel beam of microwaves of wavelength lambda = 0.5 mm falls on aYoung's double- slit apparatus. The separation between the slits is 1.0 mm. The intensity of microwaves is measured on a screen placed parallel to the plane of the slits at a distance of 1.0 m from it as shown in figure If the incient beam falls normally on the double-slit apparatus, find the order of the interference minima on the screen