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Question
A small source of sound vibrating at frequency 500 Hz is rotated in a circle of radius 100/π cm at a constant angular speed of 5.0 revolutions per second. A listener situation situates himself in the plane of the circle. Find the minimum and the maximum frequency of the sound observed. Speed of sound in air = 332 m s−1.
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Solution
Given:
Speed of sound in air v = 332 ms−1
Radius of the circle r = \[\frac{100}{\pi}\] cm =\[\frac{1}{\pi}\] m
Frequency of sound of the source \[f_0\]= 500 Hz
Angular speed \[\omega\]= 5 rev/s
Linear speed of the source is given by:
\[v = \omega r\]
⇒ \[v = 5 \times \frac{1}{\pi} = \frac{5}{\pi} = 1 . 59 \text { m/s }\]
∴ velocity of source \[v_s\]= 1.59 m/s
Let X be the position where the observer will listen at a maximum and Y be the position where he will listen at the minimum frequency.
Apparent frequency \[\left( f_1 \right)\]at X is given by :
\[f_1 = \left( \frac{v}{v - v_s} \right) f_0\]
On substituting the values in the above equation, we get:
\[f_1 = \left( \frac{332}{332 - 1 . 59} \right) \times 500 \approx 515 \text { Hz }\]
Apparent frequency \[\left( f_2 \right)\] at Y is given by:
\[f_2 = \left( \frac{v}{v + v_s} \right) f_0\]
On substituting the values in the above equation, we get:
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