# Doppler Effect Problem

1. Mar 20, 2008

[SOLVED] Doppler Effect Problem

1. The problem statement, all variables and given/known data

A submarine (sub 1) travels through water at a speed of 8.00 m/s, emitting a sonar wave at a frequency of 1400 Hz. The speed of sound in the water is 1533 m/s. A second submarine (sub 2) is located such that both submarines are traveling directly toward each other. The second submarine is moving at 9.00 m/s. While the subs are approaching each other, some of the sound from sub 1 reflects from sub 2 and returns to sub A. If this sound were to be detected by an observer on sub A, what is its frequency?

2. Relevent equations:

Doppler Equations:
Observed frequency = Actual frequency[(velocity of sonar + velocity of observer)/(velocity of sonar- velocity of source)]

Using the above equation, I found that the frequency observed by sub 2 was 1385 Hz. I noted that this frequency was also the frequency of the wave reflected off of sub 2. I substituted this frequency for the actual frequency in a new Doppler equation taking the velocity of sub B (the source) to be 0 m/s and found that the frequency observed by sub 1 was 1392 Hz. Would you please advise whether I'm correct?

I'm only asking because the textbook and my professor says I'm wrong.

Last edited: Mar 20, 2008
2. Mar 20, 2008

### mjsd

firstly, I can't see how you get a freq at sub 2 to be smaller than 1400 Hz when the subs are approaching each other.

3. Mar 22, 2008

I mistakenly wrote that the observed frequencies of the second and first subs were "1385 Hz" and "1392 Hz" respectively. I actually found that the observed frequencies of the second and first subs were 1415.6 Hz and 1423 Hz respectively. Would you please advise whether this answer is correct as opposed to the textbook answer of 1431.4 Hz? Thanks for your help.

Last edited: Mar 22, 2008
4. Mar 22, 2008

### mjsd

i think 1431Hz is what I've got

5. Mar 22, 2008

But isn't the frequency that the second sub observes equal to the frequency that it reflects, i.e. 1415.6 Hz?

Last edited: Mar 22, 2008
6. Mar 22, 2008

### mjsd

sure, the reflected wave is 1415Hz.
You problem is getting the relative velocity incorrect (from looking at your answer of 1423 Hz). Probably confused with the reference frame that you are using.
remember, the first and foremost thing in these type of problems is not go to the formula straight away but to first select your coordinate system/ref frame and then express all variables in that frame before proceeding.

7. Mar 24, 2008

My frame of reference was a stationary point on the Earth. To have any other reference point would needlessly complicate things. I took the speed of the sound, relative to my reference point, to be a constant 1533 m/s. Likwise, I took the speeds of the first and second subs, relative to my reference point, to be 8 and 9 m/s respectively.

If you agree that the frequency reflected by the second sub is about 1415 Hz, then why do you disagree that the frequency observed by the first sub is 1423 Hz?

8. Mar 24, 2008

All I need is a definite authoritative snswer on this problem before this thread makes it to the circular file..."Doc Al", please help...

9. Mar 27, 2008

10. Mar 27, 2008

### Snazzy

The sonar frequency reaches sub 2 when both sub 1 and sub 2 are moving:

$$f_1=f\frac {V + V_{sub1}}{V-V_{sub2}}$$

The reflected frequency reaches sub 1 when both sub 2 and sub 1 are moving:

$$f_2=f_1\frac {V + V_{sub2}}{V-V_{sub1}}$$

Your answer of 1415.6 Hz would be right if they asked what the frequency was at sub 2 without any reflection. Since it is going two ways with both ships moving, you need two equations.

Last edited: Mar 27, 2008
11. Mar 27, 2008

But again, isn't the frequency that is observed by sub 2 equal to the frequency that is reflected by sub 2? In that case, the I assume the velocity of sub 2 would not be relevant to the second Doppler equation.

12. Mar 27, 2008

### Snazzy

But both ships are moving during the initial transmission, and during the reflected transmission. You can't do relative velocities with Doppler questions; you'll get an answer close to the actual answer, but not quite.

13. Mar 27, 2008

Do we agree that the frequency observed by sub 2 (f prime) is equal to the frequency that is reflected by sub 2? This question is asked to identify where it is that we disagree.

14. Mar 27, 2008

### Snazzy

I agree, but it won't be the same frequency as it would be if sub 2 was just sitting there.

15. Mar 27, 2008

So you're saying that if sub 1 were to put the brakes on all of a sudden it wouldn't detect the same frequency that is oberved by sub 2?

16. Mar 27, 2008

### Snazzy

That's right, mate.

17. Mar 27, 2008

So this is where we disagree. I have been trying to argue for the past week that the frequency that is detected by any object will be the SAME frequency that the object emits/reflects. This is the case whether the object is moving or not (so long as the object is moving on an axis parallel to the velocity of the wave). Please give this some thought before responding.

Last edited: Mar 27, 2008
18. Mar 28, 2008

### mjsd

Sorry, i've been away.

the reason you get 1423 Hz, "I think" is because you used 9 m/s as the speed your moving source rather than 8+9=17m/s. You have to be ultra carefull when doing this in the frame of the Earth.. I used the frame of the first sub (ie. frame moving at 8 m/s towards sub 2), and so the relative velocity between the two subs was always 17m/s.

assuming that the reflected wave has the same freq as the incident wave is ok i think.

19. Mar 28, 2008

First, I'd like to thank you Snazzy and Mjhd for your assistance with this problem.

So I used the first Doppler equation to find the wave frequency that is DETECTED by sub 2...

$$f_2=f_1\frac {V + V_{sub2}}{V-V_{sub1}}$$ which equals 1416 Hz

I noted that this 1416 Hz is also the frequency that is REFLECTED by sub 2. So now we're dealing with waves of f= 1416 Hz directed toward a moving object, i.e., sub 1. Sub 2 now has NOTHING to do with the second Doppler equation to find the wave frequency DETECTED by sub 1, which is...

$$f_1=f_1\frac {V + V_{sub1}}{V}$$ which equals 1423 Hz