Doppler Effect; Two Moving Objects

AI Thread Summary
Two automobiles are traveling towards each other at speeds of 90 km/h and 60 km/h, both emitting a horn frequency of 524 Hz. To calculate the frequency heard by each driver, the Doppler Effect must be applied, considering both the moving source and the moving observer. The correct approach involves using combined formulas for the Doppler Effect, accounting for the relative speeds of the cars with respect to the ground and air. The resulting frequencies calculated are approximately 593 Hz for the first car and 594 Hz for the second car. Understanding the setup of the Doppler effect in this scenario is crucial for accurate calculations.
MAtkinson
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Homework Statement



Two auto-mobiles are driving on the same road in opposite directions. The speed of the first auto-mobile is 90.0 km/h and that of the second is 60 km/h. The horns of both auto-mobiles emit tons of frequency 524 Hz. Calculate the frequency that the driver of each auto-mobile hears coming from the other auto-mobile.

Homework Equations



Doppler Effect

1. For a Moving Source and Stationary Object
f=fv/(v-vsource)

The Attempt at a Solution



Car one (90km/h) is moving 30 km/h toward the other.

f=524*340/(340-30)



Answer {593Hz, 594Hz}
 
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MAtkinson said:
Car one (90km/h) is moving 30 km/h toward the other.
How did you arrive at this?

Both cars are moving with respect to the road (and air) towards each other. You also need to revise your formula, since both observer and source are moving.
 
Wow never-mind that statement it would the cars would appear to be moving 150 km/h toward each other. But I'm still confused on how to setup the Doppler effect.
 
MAtkinson said:
Wow never-mind that statement it would the cars would appear to be moving 150 km/h toward each other. But I'm still confused on how to setup the Doppler effect.
Don't worry about their relative speed, but their speeds with respect to the ground/air. Just like there's a Doppler formula for a moving source, there's one for a moving observer. Here both source and observer are moving, so you must combine both formulas.
 

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