Two loudspeakers radiate in phase at `170 H_(Z)`. An observer sits at `8 m` from one speaker and `11 m` from the other . The intensity level from either speaker acting alone is `60 dB`. The speed of sound is `340 m//s`. Find the observer intensity when both speakers are on together.

Two speakers S_(1) and S_(2) derived by the same amplifier and placed at y = 1.0 m and y = - 1.0 m (Fig . 7.9) The speakers vibrate in phase at 600 Hz . A man stands at a point on the x - axis at a very large distance from the origin and starts moving parallel to the Y - axis . The speed of sound in air is 330 m//s . (a). At what angle will the intensity of sound drop to a minimum for the first time ? (b) At what angle will the sound intensity be maximum for the first time ? (c ) If he continues to walk along the line , how many more maxima can he hear ?

Two identical speakers emit sound waves of frequency 680 H_(Z) uniformly in all directions with a total audio output of 1 mW each. The speed of sound in air is 340 m//s . A point P is a distance 2.00 m from one speaker and 3.00 m from the other. (a) Finf the intensity I_(1) and I_(2) from rach speaker at point p separately. (b) If the speakers are driven coherently and in phase, what is the intensity at point p ? (c ) If they driven coherently but of phase by 180^(@) , what is the intensity at point P ? (d) If the speakers are incoherent, what is the intensity at point p ?

two pipes have each of length 2 m, one is closed at on end and the other is open at both ends. The speed of sound in air is 340 m/s . The frequency at which both can resonate is ?

Two speakers separeted by some distance emit sound of the same frequency. At some point P the intensity due to each speaker separately is I_(o) . The path difference from P to one of the speakers is (1)/(2) lambda greater than that from P to the other speaker. What is the intensity at P if (a) the speakers are coherent and in phase, (b) the speakers are incoherent, and (c ) the speakers are coherent but have a phase different of 180^(@) ?

An observer A fires a gun and another observer B at a distance 1650 m away from A hears its sound. If the speed of sound is 330 m/s, Find the time when B will hear the sound after firing by A.

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.

The time interval between a lightning flash and the first sound of thunder is 5 s. If the speed of sound in air is 330 m s^(-1) , find the distance of flash from the observer.

Figure shows a tube having sound source at one end and observe at other end. Source produces frequencies upto 10000 Hz . Speed of sound is 400 m//s . Find the frequencies at which person hears maximum intensity.

An observer A fires a gun and another observer B at a distance 1650 m away from A hears its sound. If the speed of sound is 330 m s^(-1) , find the time when B will hear the sound after firing by A.

The smoke from the gun barrel is seen 2 second before the explosion is heard. If the speed of sound in air is 340 m s^(-1) , calculate the distance of observer from gun. State the approximation used.