If `c_(s)` is the velocity of sound in air and c is rms velocity , then

If v_(m) is the velocity of sound in moist air and v_(d) is the velocity of sound in dry air then

The difference between the apparent frequency of a source of sound as perceived by the observer during its approach and recession is 2% of the natural frequency of the source. If the velocity of sound in air is 300 m/s, the velocity of the source is

At room temperature (27^(@)C) the velocity of sound in air is 330 m/s. the increase in velocity of sound when temperature is increased by 1^(@)C is

The velocity of sound in air at 0^(@)C is 331 m/s. Find its velocity when temperature rises to 91^(@)C and its pressure is doubled.

Find the temperature at which the velocity of sound in air is double the velocity of sound in air at 0^(@)C . [Hint : Use C/C_(0)= sqrt(T/T_(0)) ]

Find the temperature at which the velocity of sound in air will be 1 1/2 times of the velocity at 27^@C .

The temperature at which the velocity of sound in air becomes double its velocity at 0^(@)C is

Velocity of sound in air is 332 ms^-1 . Its velocity in vacuum will be

If c_(0) and c denote the sound velocity and the rms velocity of the molecules in a gas, then

A source of sound attached to the bob of a simple pendulum execute SHM . The difference between the apparent frequency of sound as received by an observer during its approach and recession at the mean frequency of the source . The velocity of the source at the mean position is ( velocity of sound in the air is 340 m//s ) [Assume velocity of sound lt lt velocity of sound in air ]