What's wrong with these pictures?

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In summary: A's world line intersects the light pulse circle at the point where the observer is located. In the... image, the observer B's world line intersects the light pulse circle at the point where the observer is located. In summary, In the first image, A measures themselves as being in the centre of the circle and in the second image, they measure themselves as being at the bottom of the circle.
  • #1
nitsuj
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It took me a while to finally see where the following scenario is wrong.

I found it a "fun one" to consider.Scenario
Observer A moving at 0.5c compared to observer B.

Observer A sends out an idealized light pulse in a perfect circle. Perhaps by using a single light source & through diffraction of sorts is redirected in a perfect circle, expanding outwards at c.

Image one is from the PoV of observer B who I'll say is at rest.

Image two is from the PoV of A who is moving at 0.5c compared to B.

a.png
two
b.png

Ignore the difference in diameter (timing of the image).

I had always been confused how observer A could determine that B measures them self at the centre of the circle. Given observer A sees them near the "top" of the circle, I was able to explain the "contracted" length that is "seen" near to top of the circle, but had no clue what explains the "elongation" at the bottom.

After sometime, I finally realize that my scenario is a fallacy. ( at least I think it is)
 
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  • #2
I am not sure why you are referring to elongation. Each observer would see themselves as being at the centre of an expanding perfect circle of light. One way to demonstrate this is with the following thought experiment. Imagine A has a circle of mirrors attached to him with a radius of 1 light second and B is attached to a similar circle of mirrors. When they pass close by each other at a relative velocity of 0.5c a static electricity spark between them causes a flash of light to be emitted. Exactly 2 seconds later (by A's clock), A will see the reflected flash return simultaneously from all A's mirrors and B will also see a flash reflected back from all B's mirrors simultaneously, (exactly 2 seconds later as measured by B's clock). The situation is perfectly symmetrical.
 
  • #3
The ruler is contracted in the direction of motion. Please explain how observer A measures themselves in the centre.
 
  • #4
It might help to draw a spacetime diagram of the lightcone of flash event,
and each inertial observer's worldline (through that event)
and that observer's [hyper]plane of simultaneity.

On each observer's plane of simultaneity,
the lightcone events on that plane are equidistant from that observer's worldline event on that plane.
 
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  • #5
Are you saying there is nothing wrong with the above scenario & pictures?

How is it both observer A & B would measure the idealized light pulse as a perfect circle?
 
  • #6
Can you see your pictures in my avatar?
 
  • #7
yea, It's a good one! In the "rest frame" image below I can "see" length contraction (A). That is I know, since c is constant Observer A would measure themselves in the centre of the light pulse circle, I can understand that due to a contracted ruler observer A measures a longer distance to the light pulse in front then the "contracted" space seen from the "rest" FoR image.

How can observer B account for observer A's measure of length to the "rear" of the circle (B) that would place them in the centre? (this is practically giving up the fallacy of the scenario)

These images are like spacetime diagrams. These images have spatial axis, numerous time axis (depending on how you "cut it") and an event. The image below is the boosted/primed one. Actually the more I think of it this is very similar to a light cone, this image is from the top looking down on the event (which is an observer in this case, the event was the pulse of light which happens to originate with the observer). Simply treat the Circle of the light pulse as the null line (which it is).
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  • #8
yuiop said:
I am not sure why you are referring to elongation. Each observer would see themselves as being at the centre of an expanding perfect circle of light.

Kinda misunderstood the scenario, A is in motion and only A generates the pulse.

The first image is how observer B sees the scenario (this is why I can say observer B is at rest)

The second image is how Observer A measures the scenario.

How can you account for the measure of the "bottom" length as performed by observer A; who measures them self in the centre of the circle.

Just to be crystal clear the letters A & B in the above image are just for identifying two measurements; not the two observers.
 
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  • #9
nitsuj said:
Just to be crystal clear the letters A & B in the above image are just for identifying two measurements; not the two observers.
None of your images are crystal clear. I have no idea what you are trying to portray. Why do you think anyone looking at your drawings and with the help of you explanations would have any idea what you are trying to convey?

For example, in your first and last images, there is a faint line going up from the bottom of the picture into the circle but not in your second image. What does it represent and why is it not in the second image?

Next to the top of this faint line, there is something that looks like text in a font so tiny that it is unreadable. What is that? And why in the second image does similar feature appear a little below and to the right of the center of the circle?

In your last image you explain that A and B are not the observers called A and B. Can you understand why this could be confusing? In any case, it's still confusing because in your first post, you said the first image, which looks like something is moving, is for B, who is at rest and the second image, which looks stationary, is for A, who is moving. Then in your last image, it looks like you have added detail to the first image, but again, this is for B, who is not moving.

You said in your first post that this issue is a "fun one". I can help you maximize your fun by directing you step by step how to arrive at the correct images and conclusions but it will take a lot of work on your part and it will take a lot of time, but it will be a lot of fun and you will learn a lot. Or I could just show you the bottom line (image) and it will be all over in one post. Which do you prefer?
 
  • #10
I preffer you just tell me why you think the above scenario is not correct. I already know why it is not correct.

The main thing to consider with this scenario is that both observer A & B see the image as a perfect circle.


"Why do you think anyone looking at your drawings and with the help of you explanations would have any idea what you are trying to convey?"

You an ***. How about because it is clear what the scenario is. What about it confuses you? the irrelevant line in one image but not the other, the fact the two different measures & two different observers are both identified with A / B. yea that's super complicated.

The scenario is describe with two sentences. And what each observer measures is in two images. Info overload!
 
  • #11
nitsuj said:
I preffer you just tell me why you think the above scenario is not correct.
Your first image looks to me like it is for observer A who is traveling, not observer B. That's one thing wrong.

Your second image looks to me like it is for observer B who is at rest. That's two things wrong.

You indicated that each observer is determining that the other observer is at the center of the circle of light. That's wrong. Each observer determines that he himself is at the center of the circle of light, he has no opinion about the other observer.

You indicated that one of the observers concludes that he is near the top of the circle and far from the bottom of the circle but you have not explained how he makes that determination. It's wrong for you to make such statements without telling us how the observer is supposed to figure this out.

Justin, I'm trying to help you. Please cooperate with me.
 
  • #12
nitsuj said:
Kinda misunderstood the scenario, A is in motion and only A generates the pulse.

It makes no difference who generates the pulse. The pulse could be generated by A, by B, or by somebody else moving relative to both of them.

It's also misleading to say that A is in motion and B is at rest: A is in motion relative to B and B is in motion relative to A.

The situation is, as others have remarked symmetric: each observer sees himself as the centre of the circle (or sphere, is we are in a world with 3 spatial dimensions) and each observer sees the other observer moving away from the centre.

In order to understand why this is so, you need to think about relativity of simultaneity. Imagine that observer B is standing at the midpoint between two trees, one "below" and one "above" him in your diagram. He sees the light hit both trees at the same time. Observer A, moving relative to B and the trees, does not see the light hitting the two trees at the same time.
 
  • #13
k, so only Observer A makes a light pulse. Both images are of Observer A.

Image one is what Observer B sees when looking at A. This is because A is moving, B sees A in the position shown in the first image. I hear you ghwellsjr about the pictures not being very clear. In the first image, observer B is seen near the top of the circle, at the end of the blue line that indicates the motion of A.


Image two, is how Observer A would see them self.


In the second image A observes them self in the centre of the circle.



For you to spot the "fallacy" in the scenario, you have to understand which frame each image is observed from. Is it clear now?
 
  • #14
Michael C said:
It makes no difference who generates the pulse. The pulse could be generated by A, by B, or by somebody else moving relative to both of them.

It's also misleading to say that A is in motion and B is at rest: A is in motion relative to B and B is in motion relative to A.

Actually it does matter, what a lame response. How about you understand from the description of the scenario that only A makes the pulse, relative to the event of generating the pulse A is in motion. B relative the event of generating the pulse is stationary.

So tell me why it doesn't matter who is moving? That doesn't even makes sense in this scenario. Your analysis of this scenario is way off.
 
  • #15
Michael C said:
In order to understand why this is so, you need to think about relativity of simultaneity. Imagine that observer B is standing at the midpoint between two trees, one "below" and one "above" him in your diagram. He sees the light hit both trees at the same time. Observer A, moving relative to B and the trees, does not see the light hitting the two trees at the same time.

In order to see the fallacy in the scenario you need to think about relativity of simultaneity.
 
  • #16
nitsuj said:
Actually it does matter, what a lame response. How about you understand from the description of the scenario that only A makes the pulse, relative to the event of generating the pulse A is in motion. B relative the event of generating the pulse is stationary.

How can you define "in motion" or "stationary" relative to an event?
 
  • #17
Michael C said:
It makes no difference who generates the pulse. The pulse could be generated by A, by B, or by somebody else moving relative to both of them.

That is correct for special relativity.
The speed of light is independent of the source.

In other words, the light cone of the flash event is a property of the event... not of any worldline meeting that event.

It's best to simply say that there is a flash event when the two objects meet.
 
  • #18
robphy said:
That is correct for special relativity.
The speed of light is independent of the source.

In other words, the light cone of the flash event is a property of the event... not of any worldline meeting that event.

It's best to simply say that there is a flash event when the two objects meet.


I'm gunna point out the "fallacy" with the scenario as presented.

yes micheal c is right regarding relative motion, but it does matter as far as the shape of the light pulse. This is because of RoS.

Because A is in motion & is the one who emits the light pulse to make a circular light pulse image, it would not be seen as circular to any other observer in relative motion with A.

The fallacy of the scenario is in both FoR the image is presented as a circle, which is incorrect due to RoS. Interestingly, there is no spatial separation or two separate events in this demonstration of RoS.

To the point that's been made here already, c is invariant.
 
  • #19
Well, I can see it is not going to be productive to try to lead you in the right direction. I'm just going to show you the bottom line:

https://www.youtube.com/watch?v=dEhvU31YaCw \

The red guy is your observer A and the green guy is your observer B. When A meets B, a flash of light is emitted (as MichaelC said, it doesn't matter who emits it). Each of the observers carries with them their own set of mirrors that they have measured to be in a perfect circle but because of length contraction along the direction of motion, A's mirrors form an ellipse. Neither one of them can see the circle of light as it is expanding, they will only be able to tell its presummed position away from them when they see the reflections from all their own mirrors collapsing on them simultaneously. Note how they each see a different set of reflections (but only at the moment of collapse) and B's form a circle centered on the original location of the flash while A's form a displaced circle that coincides with the future location of A when he arrives at the location of the collapse at the moment of the collapse.

All of this is from the Frame of Reference in which B is stationary. Remember, Frames of Reference do not provide the observers in them with any more knowledge or insight into what is happening with the propagation of light or the motion of other observers, rather, they provide us with instantaneous knowledge of where the light and both observers are throughout the scenario because we define the propagation of light and the motion of the observers to be as such.

You need to watch this over and over again and then pretend that you are observer A (the red guy) and see if his experience is any different than the experience of observer B (the green guy.

By the way, this is exactly the scenario that yuiop asked you to imagine in post #2.
 
  • #20
ghwellsjr said:
Well, I can see it is not going to be productive to try to lead you in the right direction. I'm just going to show you the bottom line:

That's cute :smile: Hmmm... well I can see it is not going to be productive for me to try and lead you to understand this very simple scenario, I am just gunna tell you the bottom line.


Because of RoS, the two observers would not see the shape of the light pulse the same.

The scenario misrepresented this; the light pulse being circular from perspective of each FoR, it could not be.

Yes I have seen your annimation before, even reffered others to it. It's a really cool one. Mine is two still images of nearly the same scenario.
 
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  • #21
nitsuj said:
I'm gunna point out the "fallacy" with the scenario as presented.

yes micheal c is right regarding relative motion, but it does matter as far as the shape of the light pulse. This is because of RoS.

Because A is in motion & is the one who emits the light pulse to make a circular light pulse image, it would not be seen as circular to any other observer in relative motion with A.

No, that cannot be. c is a contant, the same for all observers. For any observer, the light emanating from a single flash will be seen as a growing circle (or sphere).
 
  • #22
Michael C said:
No, that cannot be. c is a contant, the same for all observers. For any observer, the light emanating from a single flash will be seen as a growing circle (or sphere).

Cool, how does A measure themselves in the centre of the circle? (c being constant is another "reason" why the issue with the scenario is misrepresentation of RoS)
 
  • #23
nitsuj said:
Cool, how does A measure themselves in the centre of the circle?
The same way B does--with mirrors placed a measured distance away in a circular pattern. Both A and B are doing exactly the same thing as far as they are concerned. It only looks different to us because we are viewing both of them from a single Frame of Reference. But it won't matter which FoR we decide to use, it will still illustrate the same experience for them.
 
  • #24
nitsuj said:
Cool, how does A measure themselves in the centre of the circle?

A measures himself at the centre of the circle, but sees B moving away from this centre. B measures himself at the centre of the circle, but sees A moving away from this centre.

Look at the animation that was just posted. Read ghwellsjr's explanation.
 
  • #25
You still need to answer this: how can you define "in motion" or "stationary" relative to an event?
 
  • #26
Michael C said:
You still need to answer this: how can you define "in motion" or "stationary" relative to an event?

Very clearly, as seen in the first image, givin the details of the scenario clearly B is at "rest" relative to the event, since he sees the light pulse as circular. ( as I pointed out now, A would not see the light pulse as circular.

I'll post an image showing what A sees, if B sees the light pulse as a circle. It might make it more clear.
 
  • #27
Michael C said:
A measures himself at the centre of the circle, but sees B moving away from this centre. B measures himself at the centre of the circle, but sees A moving away from this centre.

Look at the animation that was just posted. Read ghwellsjr's explanation.

Yes & length contraction accounts for the measure from the "top" of the light pulse circle, how is the measure to the bottom of the light pulse circle accounted for in the first image?

Note intervals are invariant. The interval between observer A and the bottom of the light circle is not the same as the interval with A in the centre of the circle.

Alright, so if A immits a light pulse in a perfect circle from their PoV, then here is the shape of the light pulse circle from B's PoV.



Note because of the invariance of c, "length contraction" is visable as the shape of the light pulse, of course this not actually length contraction but merely shows that A did not fire the light pulse as one event from B's PoV, from A's PoV it was a single event.

[PLAIN]http://i40.photobucket.com/albums/e204/tl01magic/aabb.jpg[/PLAIN]

The suggested image below from B's PoV is wrong.

[PLAIN][PLAIN]http://i40.photobucket.com/albums/e204/tl01magic/a.png [Broken]
 
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  • #28
nitsuj said:
Very clearly, as seen in the first image, givin the details of the scenario clearly B is at "rest" relative to the event, since he sees the light pulse as circular. ( as I pointed out now, A would not see the light pulse as circular.

You're assuming that A doesn't see the light pulse as circular and using this to produce your "definition". It doesn't make sense. An event has no velocity, it doesn't define an inertial frame. You can define motion relative to a particle, but not relative to an event.

Try this: A and B both carry a light source. When A and B coincide, both A and B send a light pulse. Two light pulses are sent, at the same time and from the same place. How can A see the light from his own source expanding in a circle and the light from the other source not expanding in a circle? That would mean that A sees the light from one source moving at a different speed to that of the light from the other source.
 
  • #29
What I thought was going to give it up for sure was A not being in the centre of the circle for both images. as clearly would be the case since there is no spatial separation and it is a "single" event. the only other thing to account for RoS is simply a disagreement on when the light was emitted from the souce, which in turn effects the shape of the light pulse.

you're assuming they both actually see a circle, because of RoS and invariant c, it cannot be the case.
 
  • #30
nitsuj said:
Yes & length contraction accounts for the measure from the "top" of the light pulse circle, how is the measure to the bottom of the light pulse circle accounted for?

Note intervals are invariant. The interval between observer A and the bottom of the light circle is not the same as the interval with A in the centre of the circle.

The length contraction formula is for rigid objects. The light circle is not a rigid object: the "bottom of the circle" and the "top of the circle" do not happen at the same times for A and for B. If B is surrounded by a circular mirror (as in the animation), he sees the light hit the "top" and the "bottom" of the mirror at the same time (in the animation, it's the right side and the left side of the mirror). For A, these two events are not simultaneous: A sees the light hit the top of B's mirror before it hits the bottom if B's mirror. Note that A sees B's circular mirror as an oval (length contraction) but A sees the light from the flash emanating in a circle.

nitsuj said:
you're assuming they both actually see a circle, because of RoS and invariant c, it cannot be the case.

Once more, any observer must see the light from a flash emanating in a circle, precisely because c is invariant.
 
  • #31
Michael C said:
Note that A sees B's circular mirror as an oval (length contraction) but A sees the light from the flash emanating in a circle.


Once more, any observer must see the light from a flash emanating in a circle, precisely because c is invariant.

1. And vice versa. But A emitts the light and has determind what makes a circle, B disagrees, says its an oval that A made. This is because the light pulse that A emmits is not simultaneous from B's perspective.


Length contraction "is for" measuremnt. Distance can be measured as length, for example the "contracted" distance infront & behind A in the direction of motion. And, the non contracted length that is perpendicular to the direction of motion.


Once more no they don;t micheal. The creation of a circular light pulse is observer dependent. Don't forget that A is in motion and is the one that determines the circular light pulse. Because A's measure of length / time is different from B's it will not look like a circle to B. Both measure the speed of the light pulse as c, that is the shape never changes.
 
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  • #32
As Michael C says... "The length contraction formula is for rigid objects. "

More precisely, "length contraction" essentially refers to the apparent spatial-separation between two parallel [in spacetime] timelike-worldlines (like two ends of a meterstick)... not the spatial-separation between a timelike worldline and a lightlike line (which, if you are about to emit another light flash, is more like [but not quite] a wavelength ).
 
  • #33
nitsuj said:
Once more no they don;t micheal. The creation of a circular light pulse is observer dependent. Don't forget that A is in motion and is the one that determines the circular light pulse. Because A's measure of length / time is different from B's it will not look like a circle to B. Both measure the speed of the light pulse as c, that is the shape never changes.

Can you clarify something for me?

Suppose observers Alice and Bob each carry a flashlight.
When Alice and Bob meet at event O, both momentarily turn on their flash lights.
On a spacetime diagram,
are the events on the light-cone of Alice's flash
the same events as those on the light-cone of Bob's flash?
 
  • #34
lol, oh okay, yes it is for Rigid objects, like a ruler, that measures non rigid things like distance. A great point that clairifies...

So Rob, you're saying that if A is traveling at 0.5 c and emits a circular light pulse, that "at rest" observer B sees it as a circle as well?
 
  • #35
nitsuj said:
lol, oh okay, yes it is for Rigid objects, like a ruler, that measures non rigid things like distance. A great point that clairifies...

So Rob, you're saying that if A is traveling at 0.5 c and emits a circular light pulse, that "at rest" observer B sees it as a circle as well?

If a flash is emitted at the meeting event,...

Alice will say that the set of events reached by the flash 1 sec after the meeting looks like a circle to her.
However, Bob will say that those events are not simultaneous [to him] and will [eventually] trace out an ellipse* in his reference frame.
(Note that I am referring to events that Alice say occurred 1 sec after the meeting.)

in accordance with the principle of relativity...
Bob will say that the set of events reached by the flash 1 sec after the meeting looks like a circle to him.
However, Alice will say that those events are not simultaneous [to her] and will [eventually] trace out an ellipse* in her reference frame.
(Note that I am referring here to events that Bob say occurred 1 sec after the meeting.)

Each observer is making their own cut of the light-cone of the meeting event with their own distinct plane of simultaneity.

*You could see this in the video posted by ghwellsjr, if those reflections events were marked.
Note that the emission event and the reception event in that video are at the foci of the ellipse.
 
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<h2>1. What is the purpose of asking "What's wrong with these pictures?"</h2><p>The purpose of asking "What's wrong with these pictures?" is to identify any errors or discrepancies in the images that may affect their accuracy or credibility. This question is often asked in a scientific context to ensure that the data being presented is reliable and can be used to draw valid conclusions.</p><h2>2. How do scientists determine what is wrong with a picture?</h2><p>Scientists determine what is wrong with a picture by carefully examining the image and comparing it to established standards and protocols. They may also use specialized equipment or software to analyze the picture and identify any errors or anomalies.</p><h2>3. Can a picture be wrong?</h2><p>Yes, a picture can be wrong. Pictures can contain errors such as distortions, manipulations, or misinterpretations that can affect their accuracy. It is important for scientists to carefully evaluate pictures to ensure that they are not misleading or incorrect.</p><h2>4. What are some common errors found in pictures used in scientific research?</h2><p>Some common errors found in pictures used in scientific research include image manipulation, incorrect scale or resolution, lack of proper labeling or annotations, and selective cropping or editing. These errors can lead to inaccurate or biased results and should be avoided in scientific research.</p><h2>5. How can scientists prevent or correct errors in pictures?</h2><p>Scientists can prevent or correct errors in pictures by following established protocols and standards for image acquisition, using reliable and calibrated equipment, and carefully examining and validating their data. If errors are identified, they should be addressed and corrected before the data is used for analysis or publication.</p>

1. What is the purpose of asking "What's wrong with these pictures?"

The purpose of asking "What's wrong with these pictures?" is to identify any errors or discrepancies in the images that may affect their accuracy or credibility. This question is often asked in a scientific context to ensure that the data being presented is reliable and can be used to draw valid conclusions.

2. How do scientists determine what is wrong with a picture?

Scientists determine what is wrong with a picture by carefully examining the image and comparing it to established standards and protocols. They may also use specialized equipment or software to analyze the picture and identify any errors or anomalies.

3. Can a picture be wrong?

Yes, a picture can be wrong. Pictures can contain errors such as distortions, manipulations, or misinterpretations that can affect their accuracy. It is important for scientists to carefully evaluate pictures to ensure that they are not misleading or incorrect.

4. What are some common errors found in pictures used in scientific research?

Some common errors found in pictures used in scientific research include image manipulation, incorrect scale or resolution, lack of proper labeling or annotations, and selective cropping or editing. These errors can lead to inaccurate or biased results and should be avoided in scientific research.

5. How can scientists prevent or correct errors in pictures?

Scientists can prevent or correct errors in pictures by following established protocols and standards for image acquisition, using reliable and calibrated equipment, and carefully examining and validating their data. If errors are identified, they should be addressed and corrected before the data is used for analysis or publication.

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