A truck is traveling at 74.5 kilometers per hour away from you. The driver is blowing the horn which has a frequency of 415 Hz. The speed of the sound is 346 m/s. What is the observed frequency of the sound?

fo = 335 Hzlet fo = frequency heard
f = actual frequency
v= speed of sound
vs = speed of source

For the first one,
fo = fv/(v - vs)
74.5 km/h = 20.69 m/s
vs = -20.69m/s since it is moving away from you

fo = (415Hz)(346m/s)/(346m/s - (-20.69m/s))
fo = 392 Hz

For the second one,
fo = fv/(v - vs)
82.8 km/h = 23 m/s
vs = 23m/s

fo = (312Hz)(331m/s)/(331m/s - (23m/s))

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tardymanchester tardymanchester · Answer 2 · 2019-04-10T09:18:25+02:00

Answer:

The observed frequency is 391.3 Hz.

Step-by-step explanation:

Given : A truck is traveling at 74.5 kilometers per hour away from you. The driver is blowing the horn which has a frequency of 415 Hz. The speed of the sound is 346 m/s.

To find : What is the observed frequency of the sound?

Solution :

Let, f be the observed frequency

[tex]f_0=415 hz[/tex] be the frequency heard

v=346 m/s be the speed of sound

[tex]v_s[/tex] speed of truck

Distance traveled by truck [tex]d= 74.5 km = 74.5 \times 1000[/tex]

Time taken = 1 hour = 3600 sec.

We know, [tex]\text{Speed}=\frac{\text{Distance}}{\text{Time}}[/tex]

[tex]v_s=\frac{74.5 \times 1000}{3600}[/tex]

[tex]v_s=20.69m/s[/tex]

This is the Doppler effect.

The formula is given by,

[tex]f=f_0(\frac{v}{v+v_s})[/tex]

[tex]f=415(\frac{346}{346+20.69})[/tex]

[tex]f=415(\frac{346}{366.69})[/tex]

[tex]f=415(0.943)[/tex]

[tex]f=391.345[/tex]

Therefore, The observed frequency is 391.3 Hz.