Debate: Zero Doppler effect for reflected light from a rolling wheel

Moderator note: The full, agreed topic of this debate is:

"That that the light reflected off the circular rim of a mirror-like wheel shows zero Doppler effect between the source and the receiver in the case of the wheel rolling without slipping"

Debaters: Tach for the affirmative; James R for the negative.

Standard rules apply.

[thread=110880]Proposal thread[/thread]
[thread=110905]Discussion thread[/thread]

Tach's opening post follows:

----

I claim that :

"The light reflected of the circular rim of a mirror-like wheel shows zero Doppler effect between the source and the receiver in the case of the wheel rolling without slipping" . The speed may or may not be relativistic, it doesn't really matter.

The formal proof is here

 

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Thank you. Despite all your previous claims I have no qualms debating with you.

Actually, ignoring my document is not OK since it provides you (and the others) with the rigorous proof of the thread claim because whatever diversion you took, it does not disprove the information given to you in the opening post, the Doppler effect is still null for the cases described in post 1. You should have read it first and you should have tried to refute the claim shown in the file. Instead , you elected to construct your own, cartoonish version of the exact case.

No, that would not wash since you are not addressing the claim of the OP but rather generating your own, cartoonish version of the scenario.

A radar gun is not a camera, and you just moved the observer and the light source in the same point in space, so you have just moved the goalposts.
You need to consider instead the case shown to you in the detailed writeup, the wheel is either rolling away from the light source and approaching the camera or it is rolling towards the light source and rolling away from the camera. The description explains why there is no net Doppler effect in the way the rolling wheel reflects the light. If you engage in a debate, you need to understand its parameters as outlined in the detailed mathematical description I linked at post 1, not to make up your own description. Your simplistic treatment covers neither of the two cases explained to you in the opening post of the debate.

The above is only partially correct (and certainly incorrect for the case in discussion). You have been given the general equation (formula 1 in the writeup):

\(f_{mirror}= \frac{\sqrt{1-(v/c)^2}}{1+(v/c) cos (\phi)} f_{source}\)
(1)

valid for a mirror receding from the source. The angle \(\phi\) is the angle between the mirror velocity (in our case a point on the circumference of the wheel) and the direction of the incident ray (see the standard description of the relativistic Doppler effect). Only for the PARTICULAR case of \(\phi=0\) one gets the formula:


\(f_{mirror}=f_{source} \sqrt{\frac{1-(v/c)}{1+(v/c)}}\)

Now , looking at the attached figure, one understands immediately that \(\phi=0\) only for the two incident rays tangent to the wheel. NEITHER of these two rays ever returns to the camera, let alone to the gun.

At the very WORST, you should have gotten the above and not what you wrote, i.e.

\(f_w = f_s\sqrt{\frac{1+v/c}{1-v/c}}\)

is clearly wrong. Moreover and unfortunately for your argument, the simplistic formula that you are employing is useless for the case in study clearly described to you in the first post of the debate since \(\phi\) ISN'T zero in the general case outlined in the opening post of the debate. This is the FIRST mistake in your argumentation.

Incorrect. Remember that the wheel is rolling, so, the light is NOT propagating back to the source (the gun) but onwards to the camera. See fig. 2 in the writeup (or the picture attached to the bottom of this post). As the wheel (mirror) recedes from the source it also approaches the camera, thus the red-shift due to receding is cancelled out by the blue-shift due to it approaching the camera. This is your SECOND mistake.

This is , again, overly simplistic, since it is valid ONLY for the PARTICULAR case of the angle between the velocity of the mirror and the reflected (secondary) ray is (formula 2 in the writeup):

\(f_{camera}=f_{mirror} \frac{1+(v/c)cos(\phi)}{\sqrt{1-(v/c)^2}}\)
(2)


For the trivial (and useless) case when \(\phi=0\) one recovers the trivial formula:


\(f_{camera}=f_{mirror} \sqrt{\frac{1+(v/c)}{1-(v/c)}}=f_{source}\)


Turns out that, if you use the CORRECT formulas (1) and (2) for the Doppler effect, you get \(f_{camera}=f_{source}\) for all angles \(\phi\) and for all speeds \(v\). This is quite intuitive since the wheel circumference is either rolling away from the source and towards the camera or vice-versa (see fig 2).

You elected to treat a dumbed down scenario. This is the THIRD and most fatal mistake. Now, in this dumbed down scenario, where you merged the camera and the light source into your radar gun, you will have indeed the trivial situation that the radar gun will get ONLY one ray reflected back (the one that lines up with the center of the wheel). You will not get a picture of the rolling wheel from your radar gun and this is not what the thread is about. It is true, that in this trivial case:

\(f_{reflected}=\frac{1+v/c}{1-v/c} f_S\)

for wheel approaching the gun and

\(f_{reflected}=\frac{1-v/c}{1+v/c} f_S\)

for the wheel receding from the gun (using your notation).

Nope, you did not even make the effort to understand the explanation from post 1 and replaced the scenario with your dumbed-down version. You did not address the case described in the opening post. This is why I was so insistent on getting the exact title and the exact description, so you could not move the goal-posts with a dumbed-down version of the scenario.

Luckily, the people from references [1-3] got things right and they show NO Doppler effect in the colors of their rolling wheels. If what you are claiming were true (it clearly ISN'T) the color of the wheels in their animations would have looked severely Doppler shifted. They don't because the authors knew what they were doing.

Actually, it turns out that your claim is easily proven to be in error: I have taken the trouble to understand and address your position whereas you have not bothered to understand the original claim and you have not addressed it. I guess that you have one more shot at doing that....

References:

[1] V.F.Weisskopf, “The Visual Appearance of Rapidly Moving Objects”, Physics Today 13, 24 (1960)
[2] U. Kraus, H. Ruder, D. Weiskopf, C. Zahn, "Was Einstein noch nicht sehen konnte - Visualisierung relativistischer Effekte", Physik Journal, 7/8, (2002)
[3] http://www.spacetimetravel.org/rad/rad.html

 

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There are two issues with your approach:

1. (The lesser one) You have used a specific case of radar propagation to show that there is Doppler shift for a wheel rolling in the dumbed down case when the emitter and receptor are ONE and the SAME. (the radar gun). Of course, this doesn't cover any of the interesting cases of a wheel rolling between an emitter and a receptor that are DIFFERENT from each other. It is my fault that I allowed the description to be not as tight as necessary, giving you the opportunity to weasel out of dealing with the case that was presented quite clearly in the opening post, a case that you clearly HAVE NOT addressed and you have avoided addressing ever since. The origin of the current debate traces all the way back to your false claim in post 241 that you have found errors in my treatment of the issue of a mirror-like object traveling between a light source and a camera.

2. (The bigger one). Don't be so quick to declare "I win the debate" since there is more than ample evidence in mainstream literature that (for non trivial cases), "there IS evidence of ZERO Doppler shift for a wheel rolling between a source and a camera".

No, this is a gross misrepresentation of what I said: the wheels do not have to always roll BETWEEN the source and the camera, to prove my stance it is SUFFICIENT that they roll this way just in the example outlined in the opening argument in this thread, an example that you have not taken the time to either understand, let alone to refute. This is all I claim and it is the sufficient condition to prove the statement in my OP correct, thus disproving your stance.

No, I understood your scenario all right, this is why I made the effort to play it back to you while outlining the differences in the assumptions between the case I described to you and the dumbed-down case you insist on presenting. While I made the effort to understand your scenario (it is quite trivial, really), you never made the effort to understand mine, so, in effect, you never responded to the claims in the OP. What you also fail to mention, is that if we cast your scenario into the case when the mirror moves between the light source and the camera (see references [4,5]), say away from the light source and towards the camera, you get a NULL Doppler effect, as explained to you multiple times even before this debate started. Here is again the explanation why there is no Doppler effect in this scenario:

\(f_{mirror}=\sqrt{\frac{1-v/c}{1+v/c}} f_{source}\) (redshift due to the mirror moving away from the source)
\(f_{camera}=\sqrt{\frac{1+v/c}{1-v/c}} f_{mirror}\) (blueshift due to mirror moving towards the camera)

Conclusion: \(f_{camera}=f_{source}\), clearly contradicting your strawman argument. If you don't agree with that, I suggest you consult references [1-5]. take for example reference [3], despite of the fact that the speeds of different components of the wheel vary from point to point between 0 and \(2v\), the color of the wheel is uniform, i.e. there is no Doppler shift. And there shouldn't be, as explained in the math above....

Now, evidence for the above has been provided to you much earlier for translation motion, in this file, in the other thread, and, again, for the case of rolling motion, in the current thread. In NEITHER cases, did you address the issue, let alone refute it. You have been provided with direct evidence that , in fact, there is NO Doppler effect in the cases described in this thread (and in the "rolling wheel" thread) for light being reflected off moving object (translation or rolling motion). You never addressed either.

As such, the claim stands, for not so trivial situations, (i.e, non-cartoon ones as the one in your scenario), there is NO Doppler effect for light bouncing off moving objects. Since you have also disregarded the references [1-3] from peer reviewed journals given to you in my earlier post, I will provide you with two more [4-5]. So, now you have not only to rebut my writeup, you also need to rebut mainstream, peer reviewed papers on the same exact subject. You see, the funny thing is that the fact that the Doppler effect is null for the case of surfaces moving parallel to themselves has been known for over 100 years (see ref. [4]), the case of the rolling wheel is just a direct application of the case for translation motion (each infinitesimal portion of the wheel circumference translates parallel to itself), so, if you are thinking that you have refuted me, you are also deluding yourself into thinking you refuted all these people who wrote references [1-5], same goes for all these guys on your cheerleading squad. Pete almost got it right in posts 30 and 44 of the "Discussion" thread but he still thinks (incorrectly, see his back-peddaling in post 45) that the null effect applies only for one specific point on the circumference, hopefully sooner rather than later he'll realize that it holds for all points on the circumference. Given that you stedfastedly avoided addressing the OP and you replaced the OP discussion with a discussion on a mockery of the scenario I described for you, could you at least, address the mainstream references I have given you (work with [5], for example, it is the easiest one to obtain, if you don't have it, I will upload the whole chapter for you) such that you learn how to deal with a scientific subject without cheating. This way you will learn how to address the issue, not your own made-up scenarios.

References

[4] H . Bateman, "The reflexion of light at an ideal plane mirror moving with a uniform velocity of translation" ,Phil. Mag., (18) (1909) p.890
[5] W.Pauli, "Theory of Relativity" , 1958, Pergamon Press, p.95 (top)