Sound from coherent sources `S_(1) and S_(2)` are sent in phase and detected at point `P` equidistant from both the sources . Speed of sound in normal air in `V_(0)`, but in some part in path `S_(1)` , there is a zone of hot air having temperature ` 4 times` , the normal temperature , and width `d`. What should be minimum frequency of sound , so that minima can be found at `P`?

In an organ pipe the distance between the adjacent node is 4 cm . Find the frequency of source if speed of sound in air is 336 m//s .

A closed organ pipe can vibrate at a minimum frequency of 500 Hz. Find the length of the tube. Speed of sound in air = 340 m s^-1 .

The speed of sound in air is 330 m s^(-1) and in water is 1650 m s^(-1) . It takes 2 s for sound to reach a certain distance from the source placed in air. Find the distance.

Speed of sound in air is 330m//s .Find maximum and minimum wavelength of audible sound in air.

At normal temperature and pressure, the speed of sound in air is 332 ms^(-1) . What will be the speed of sound in hydrogen (i) at normal temperature and pressure (ii) at 819^@C temperature and 4 atmospheric pressure. Given air is 16 times heavier than hydrogen.

Two identical sources of sound S_(1) and S_(2) produce intensity I_(0) at a point P equidistant from each source . (i) Determine the intensity of each at the point P . (ii) If the power of S_(1) is reduced to 64% and phase difference between the two sources is varied continuously , then determine the maximum and minimum intensities at the point P . (iii) If the power of S_(1) is reduced by 64% , then determine the maximum and minimum intensities at the point P .

An echo is returned in 3 s . What is the distance of the reflecting surface from the source, given that the speed of sound is 342 m//s .

In the case of light waves from two coherent sources S_(1) and S_(2) , there will be constructive interference at an arbitrary point P, the path difference S_(1)P - S_(2)P is

The speed of sound in air is 330 m s^(-1) and in water is 1650 m s^(-1) . It takes 2 s for sound to reach a certain distance from the source placed in air. How much time will it take for sound to reach the same distance when the source is in water ?

In Quincke's experiment the sound detected is changed from a maximum to a minimum when the sliding tube is moved through a distance of 2.50 cm. Find the frequency of sound if the speed of sound in air is 340 m s^-1 .