A whistle of frequency 540 H(Z) rotates ...

A whistle of frequency `540 H_(Z)` rotates in a circle of radius `2 m`at a linear speed of `30 m//s` . What is the lowest and highest frequency heard by an observer a long distance away at rest with respect to the centre of circle ? Take speed of sound of sound in air as `330 m//s`. Can the apparent frequency be ever equal to actual ?

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Apparentfrequency will be minimum when the source is at N and moving away from the observer.

`f_("min") + (v/(v +v_s)) f =(330/(330 +30)) xx 540 = 495 Hz`
Frequency will be maximum when source is at L and approachign the observer.
`f_(max) =(v/(v-v_s)) f = (330/(330 -30)) (540) = 594 Hz`
Further when source is at M and K, angle between velocity of source and line joining source and observer is `90^@" or " v_s cos theta =v_s cos 90^@ =0`. So, there will be no change in the apparent frequency. i.e., no Doppler effect.

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