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` .

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?

Two long wires, carrying currents i_1 and i_2, are placed perpendicular to each other in such a way that they just avoid a contact. Find the magnetic force on a small length dl of the second wire situated at a distance l from the first wire. (figure)

Two coherent point sources S_1 and S_2 emit light of wavelength lambda . The separation between sources is 2lambda . Consider a line passing through S_2 and perpendicular to the line S_(1)S_(2) . What is the smallest distance on this line from S_2 where a minimum of intensity occurs?

A double slit S_1-S_2 is illuminated by a coherent light of wavelength lamda . The slits are separated by a distance d. A plane mirror is placed in front of the double slit at a distance D_1 , from it and a screen sum is placed behind the double slit at a distance D_2 , from it . The screen sum receives only the light reflected by the mirror. Find the fringe-width of the interference pattern on the screen.

Consider the situation shown in figure. The two slits S_1 and S_2 placed symmetrically around the central line are illuminated by a monochromatic light of wavelength lamda . The separation between the slits is d. The light transmitted by the slits falls on a screen Sigma_1 placed at a distance D from the slits. The slit S_3 is at the placed central line and the slit S_4 , is at a distance z from S_3 . Another screen Sigma_2 is placed a further distance D away from 1,1. Find the ratio of the maximum to minimum intensity observed on Sigma_2 if z is equal to a. z=(lamdaD)/(2d) b. (lamdaD)/d c. (lamdaD)/(4d)

Figure shows two coherent sources S_1 and S_2 which emit sound of wavelength lamda in phase. The separation between the sources is 3lamda . A circular wire at large radius is placed in such a way that S_1 S_2 lies in its plane and the middle point of S_1 S_2 , is at the centre of the wire. Find the angular positions 0 on the wire for which constructive interference takes place.

Two electric trains run at the same speed of 72 km h^-1 along the same track and in the same direction with a separation of 2.4 km between them. The two trains simultaneously sound brief whistles. A person is situated at a perpendicular distance of 500 m from the track and is equidistant from the two trains at the instant of the whistling. If both the whistles were at 500 Hz and the speed of sound in air is 340 m s^-1 , find the frequencies heard by the person.

In a Young's double slit interference experiment the fringe pattern is observed on a screen placed at a distance D from the slits. The slits are separated by a distance d and are illuminated by monochromatic light of wavelength lamda . Find the distance from the central point where the intensity falls to (a) half the maximum,

Two narrow slits emitting light in phase are separated by a distance of 1-0 cm. The wavelength of the light is 5.0x10^-7 m. The interference pattern is observed on a screen placed at a distance of 1-0 m. (a) Find the separation between the consecutive maxima. (b) Find the separation between the sources which will give a separation of 1.0 mm between the consecutive maxima.

Two stereo speakers are separated by a distance of 2.40 m. A person stands at a distance of 3.20 m directly in front of one of the speakers as shown in figure. Find the frequencies in the audible range (20-2000 Hz) for which the listener will hear a minimum sound intensity. Speed of sound in air = 320 ms^-1