A wall is moving with velocity u and a source of sound moves with velocity `(u)/(2)` in the same direction as shown in the figure. Assuming that the sound travels with velocity `10u`, the ratio of incident sound wavelength on the wall to the reflected sound wavelength by the wall is equal to

When the source moves with a velocity v, the ratio of wavelengths received by A and B will be (c = speed of Sound):

A listener and a source of sound are moving with the same speed in the same direction. The ratio of the frequency of the source and the frequency which is heard by the listerner is

A car moving with a velocity v_1 overtakes a person moving with a velocity v_2 . The ratio of frequencies of sound Just before and after overtaking, is:

Can we apply Doppler effect to a source of sound moving faster than the velocity of sound?

If a ball strickes with a velocity u_(1) at the wall which itself is approaching it with a velocity u_(2) then find the velocity of the ball after collision with the wall.

The frequency of sound is 100 Hz and wavelength is 3m. Calculate the velocity of the wave.

An observer rides with a sound source of frequency f and moving with velocity v towards a large vertical wall. Considering the velocity of sound waves as c , find : (i) The number of waves striking the surface of wall per second (ii) The wavelength of the reflected wave (iii) The frequency of reflected wave as observed by observer. (iv) Beat frequency heard by the observer.

A source of sound with frequency 256 Hz is moving with a velocity V towards a wall and an observer is stationary between the source and the wall. When the observer is between the source and the wall will he hear beats?

A source of sound with frequency 256 Hz is moving with a velocity V towards a wall and an observer is stationary between the source and the wall. When the observer is between the source and the wall he will hear beats.

The source (S) of sound is moving constant velocity v_(0) as shown in diagram. An observer O listens to the sound emmited by the source. The observed frequency of the sound