`S_(1)S_(2)` are two coherent cources (having initial phase difference zero) of sound located along`x`-axis separated by `4 lambda` where `lambda` is wavelength of sound emitted by them. Number of maxima located on the ellopical boundry around it will be.

two sound sources S_(1) and S_(2) are kept symmetrically about the centre of a circle as shown. The circle is divided is 4 parts. Both the sources are separated by a 8lamda//3 distance. Where lamda is wavelength of sound emitted by the sources. A detector is moving around the circle. How many times it will detect a minima in II part if S_(1) is leading S_(2) by phase of 2pi//3 ?

S_(1) and S_(2) are two coherent sources of sound having no intial phase difference. The velocity of sound is 330 m//s . No maximum will be formed on the line passing through S_(2) and prependicular to the line joining S_(1) and S_(2) . If the frequency of both the sources is

S_1 and S_2 are two coherent sources of radiations separated by distance 100.25 lambda , where lambda is the wave length of radiation. S_1 leads S_2 in phase by pi//2 .A and B are two points on the line joining S_1 and S_2 as shown in figure.The ratio of amplitudes of component waves from source S_1 and S_2 at A and B are in ratio 1:2. The ratio of intensity at A to that of B (I_A/I_B) is

S_1 and S_2 are two coherent sources of radiations separated by distance 100.25 lambda , where lambda is the wave length of radiation. S_1 leads S_2 in phase by pi//2 .A and B are two points on the line joining S_1 and S_2 as shown in figure.The ratio of amplitudes of component waves from source S_1 and S_2 at A and B are in ratio 1:2. The ratio of intensity at A to that of B (I_A/I_B) is

An interference is observed due to two coherent sources separated by a distance 5lambda along Y-axis, where lambda is the wavelength of light A detector D is moved along the positive X -axis The number of point on the X-axis excluding the points x=0 and x=infty at which resultant intensity will be maximum are

Two coherent sources S_(f) and S_(2) (in phase with ech other) are placed at a distance of 2lambda as shown where lambda is wavelength of sound. A detector moves on line A B parrallel to S_(1)S_(2) . If detector detects maximum intensity at finite distance from O at theta = +- ((pi)/(n)) . Find n

S_(1) and S_(2) are two coherent sources of sound of frequency 110Hz each they have no initial phase difference. The intensity at a point P due to S_(1) is I_0 and due to S_2 is 4I_0 . If the velocity of sound is 330m//s then the resultant intensity at P is

An interference is observed due to two coherent sources S_1 placed at origin and S_2 placed at (0, 3lambda, 0) . Here, lambda is the wavelength of the sources. A detector D is moved along the positive x-axis. Find x-coordinates on the x-axis (excluding x = 0 and x= oo ) where maximum intensity is observed.

Two identical coherent sources of wavelength lambda are placed at (100 lambda, 0) and (-50 lambda, 0) along x-axis. The number of maxima and minima detected are ,respectively [include origin and (5 lambda, 0)]

S_(1) and S_(2) in List I represent coherent point sources, S represents a point source lambda = wavelength of light emitted by the sources. Fringe pattern is observed on the screen. Exclude the position of source while detecting the fringe pattern.