The Relativity of Simultaneity: A Fundamental Concept in Special Relativity

In summary, RoS is a consequence of time dilation, which is a feature of the Lorentz transform. It is not a separate stand-alone component of SR.
  • #1
mangaroosh
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Hey guys,

this might seem like yet another basic question, but I was wondering about RoS. The impression that I got from reading about relativity was that relativity of simultaneity was a consequence of Lorentz contractions, primarily time dilation. Someone else made the point [emphasis is theirs, not mine]
ROS is a subsidiary shorthand way of using distance contraction and time dilation and is not a separate stand-alone component of SR. ROS is a SUBSTITUTE for distance contraction and/or time dilation. It is NOT an additional function.
This was effectively how I understood it, but in a discussion on here I was told that wasn't the case. As with the other concepts of relativity I'm trying to get a better understanding of it.

To try and illustrate my own understanding of it: if everything in the universe was at rest relative to each other, then there would be absolute simultaneity, but I thought that if an observer started moving relative to that previous rest frame then they would encounter time dilation and relativity of simultaneity would occur. It thought that RoS was a result of the time dilation.

Just wondering what I'm missing, and if there are any online resources that clearly explain the distinction between RoS and Lorentz contractions, and how they are different from each other?
 
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  • #2
Relativity of simultaneity is a particular feature of the Lorentz transform (in units where c=1):
[itex]t'=\gamma (t-vx)[/itex]
[itex]x'=\gamma(x-vt)[/itex]

Here is a transform which has length contraction and time dilation, but not the relativity of simultaneity:
[itex]t'=\gamma (t)[/itex]
[itex]x'=\gamma(x-vt)[/itex]

Here is a transform which has the relativity of simultaneity, but not length contraction or time dilation:
[itex]t'=t-vx[/itex]
[itex]x'=x-vt[/itex]
 
  • #3
You have to understand the concept of a Frame of Reference in order to understand Relativity of Simultaneity. In Einstein's Special Relativity, a scheme to create a coordinate system is defined in which you have three coordinates for specifying a location (x,y,z) and one coordinate for specifying time (t). Just like we have three coordinates for specifying a point in space, these four coordinates specify an event in the Frame of Reference. If you pick any two events and they have the same time coordinate, then they are simultaneous. If you then pick another Frame of Reference moving with respect to the first one, you can transform the coordinates for those two events using the Lorentz Transformation which will give you a new set of coordinates for the same two events. If the two time coordinates in the new Frame of Reference are equal to each other, then the events are simultaneous in that FoR. In general, two events that are simultaneous in one FoR will not be simultaneous in another FoR, but not necessarily.

So it has nothing to do with what is at rest or what is moving but simply the time coordinates of a pair of events in one Frame of Reference compared to another FoR.
 
  • #4
DaleSpam said:
Relativity of simultaneity is a particular feature of the Lorentz transform (in units where c=1):
[itex]t'=\gamma (t-vx)[/itex]
[itex]x'=\gamma(x-vt)[/itex]

Here is a transform which has length contraction and time dilation, but not the relativity of simultaneity:
[itex]t'=\gamma (t)[/itex]
[itex]x'=\gamma(x-vt)[/itex]

Here is a transform which has the relativity of simultaneity, but not length contraction or time dilation:
[itex]t'=t-vx[/itex]
[itex]x'=x-vt[/itex]

thanks Dalespam; I think you mentioned that before. I don't fully understand it from that, but all information is helpful
 
  • #5
ghwellsjr said:
You have to understand the concept of a Frame of Reference in order to understand Relativity of Simultaneity. In Einstein's Special Relativity, a scheme to create a coordinate system is defined in which you have three coordinates for specifying a location (x,y,z) and one coordinate for specifying time (t). Just like we have three coordinates for specifying a point in space, these four coordinates specify an event in the Frame of Reference. If you pick any two events and they have the same time coordinate, then they are simultaneous. If you then pick another Frame of Reference moving with respect to the first one, you can transform the coordinates for those two events using the Lorentz Transformation which will give you a new set of coordinates for the same two events. If the two time coordinates in the new Frame of Reference are equal to each other, then the events are simultaneous in that FoR. In general, two events that are simultaneous in one FoR will not be simultaneous in another FoR, but not necessarily.

So it has nothing to do with what is at rest or what is moving but simply the time coordinates of a pair of events in one Frame of Reference compared to another FoR.
Thanks gh.

I think I have a decent enough understanding of what a reference frame is ["I think" being the operative words]. I suppose, when thinking about simultaneity I consider it in the sense of simultaneity in the universe, as opposed to simultaneity between a limited number of events; because absolute simultaneity would be a universal phenomenon, as well as applying to a limited number of events.


As per Dalespams example, I understand that two or more events can "experience" contractions but still be "absolutely simultaneous"; presumably it would be theoretically possible that all events could "experience" contractions and still be "absolutely simultaneous"; that, however, would mean that Absolute simultaneity, not relativity of simultaneity was a "feature" of the universe.

Is it possible for RoS to be a "feature" of the universe without time dilation?
 
  • #6
mangaroosh said:
Thanks gh.

I think I have a decent enough understanding of what a reference frame is ["I think" being the operative words]. I suppose, when thinking about simultaneity I consider it in the sense of simultaneity in the universe, as opposed to simultaneity between a limited number of events; because absolute simultaneity would be a universal phenomenon, as well as applying to a limited number of events.


As per Dalespams example, I understand that two or more events can "experience" contractions but still be "absolutely simultaneous"; presumably it would be theoretically possible that all events could "experience" contractions and still be "absolutely simultaneous"; that, however, would mean that Absolute simultaneity, not relativity of simultaneity was a "feature" of the universe.

Is it possible for RoS to be a "feature" of the universe without time dilation?
It's meaningless to consider RoS for the universe as if it is something intrinsic to the universe that we have to or could learn about or discover. This is an issue of remote time. We can't talk about it until we define what we mean and since there are an infinite number of ways to define remote time, it's not going to be something that we get from nature, rather it's something we put into nature.

Events do not "experience" anything, let alone contraction. They are numbers, three for space, one for time. If those numbers for the time coordinate are identical according to the synchronization established for that FoR, then the events are simultaneous. The reason that I limited it to two is because if you have more than two, some of them can be simultaneous with each other but not with some others.
 
  • #7
ghwellsjr said:
It's meaningless to consider RoS for the universe as if it is something intrinsic to the universe that we have to or could learn about or discover. This is an issue of remote time. We can't talk about it until we define what we mean and since there are an infinite number of ways to define remote time, it's not going to be something that we get from nature, rather it's something we put into nature.

Events do not "experience" anything, let alone contraction.
Please forgive the use of imprecise terminology; I used the inverted commas to try and demonstrate that I know that isn't necessarily how we would talk about them, but in the absence of proper terminology I thought they would convey the meaning. We can abandon any mention of "feature" of the universe and "experience" and replace them with whatever words make sense when talking about contractions and simultaneity.


ghwellsjr said:
They are numbers, three for space, one for time. If those numbers for the time coordinate are identical according to the synchronization established for that FoR, then the events are simultaneous. The reason that I limited it to two is because if you have more than two, some of them can be simultaneous with each other but not with some others.

Limiting it to two is fine, but if we limit it to two then we speak about a universe in which there are only two events; if they are simultaneous then does that mean that absolute simultaneity prevails and not RoS? In saying that they can be simultaneous with each other but not with others, we are not limiting it to two, but to an undefined number of events. Of course, if they are simultaneous with each other but not with other [undefined] events, then there RoS prevails.

Could we build on this, saying that three events are simultaneous with each other but not with [undefined] others; in that case RoS prevails again, and not absolute simultaneity. I presume we could do this exponentially until we arrive at a scenario where all events are simultaneous with each other - in this case absolute simultaneity prevail, wouldn't it.

In order for RoS to prevail, I presume there would only need to be one single event where the time co-ordinate is different from all the rest [who have the same time co-ordinate]. Is this possible without there being "time" dilation?


I see Dalespam's example seems to suggest that there might, but I'm not sure how.
 
  • #8
mangaroosh said:
Please forgive the use of imprecise terminology; I used the inverted commas to try and demonstrate that I know that isn't necessarily how we would talk about them, but in the absence of proper terminology I thought they would convey the meaning. We can abandon any mention of "feature" of the universe and "experience" and replace them with whatever words make sense when talking about contractions and simultaneity.




Limiting it to two is fine, but if we limit it to two then we speak about a universe in which there are only two events; if they are simultaneous then does that mean that absolute simultaneity prevails and not RoS?
The universe contains an infinite number of events: every different location at every different instant of time is a different event. All the events that occur at the same time are simultaneous with each other. But remember, the times are all defined according to our FoR. There is no issue of RoS within a single FoR.
mangaroosh said:
In saying that they can be simultaneous with each other but not with others, we are not limiting it to two, but to an undefined number of events. Of course, if they are simultaneous with each other but not with other [undefined] events, then there RoS prevails.
This sounds like a repeat of what you just said, so ditto what I just said.
mangaroosh said:
Could we build on this, saying that three events are simultaneous with each other but not with [undefined] others; in that case RoS prevails again, and not absolute simultaneity. I presume we could do this exponentially until we arrive at a scenario where all events are simultaneous with each other - in this case absolute simultaneity prevail, wouldn't it.
There's no absolute simultaneity in SR. At every instant in time, all the locations throughout the entire universe are simultaneous events, because they all have the same time coordinate but different spatial coordinates. At the next instant in time, there is a new set of events throughout the entire universe that are another set of simultaneous events. We keep repeating this forever. But if you pick one event from the first set and another event from a subsequent set, they are not simultaneous.
mangaroosh said:
In order for RoS to prevail, I presume there would only need to be one single event where the time co-ordinate is different from all the rest [who have the same time co-ordinate]. Is this possible without there being "time" dilation?
I see Dalespam's example seems to suggest that there might, but I'm not sure how.
As I keep saying RoS is not a factor until you transform the coordinates for a pair of events in one frame into the coordinates for the same pair of events into another frame in motion with respect to the first frame. You can continue to transform any number of events to see which pairs remain simultaneous.

This has nothing to do with time dilation. Any clock that is moving in a Frame of Reference will be running at a slower rate than the coordinate clocks defining the Frame of Reference. You could have two clocks traveling at different speeds and in different directions and talk about the simultaneous events of where they both were at a particular time which has nothing to do with the times displayed on their two clocks. But when you consider a different Frame of Reference, all the coordinates of all the events take on a new set of values and events that used to be simultaneous in the first frame are no longer simultaneous in the second frame.

Let me emphasize once more: unless you consider two different Frames of Reference, you don't have any issue with relativity of simultaneity.
 
  • #9
mangaroosh said:
Limiting it to two is fine, but if we limit it to two then we speak about a universe in which there are only two events; if they are simultaneous then does that mean that absolute simultaneity prevails and not RoS?
The question about RoS isn't whether two arbitrary events are simultaneous or not, but whether two events which are simultaneous in one frame are also simultaneous in other frames.
 
  • #10
DaleSpam said:
The question about RoS isn't whether two arbitrary events are simultaneous or not, but whether two events which are simultaneous in one frame are also simultaneous in other frames.

ghwellsjr said:
They are numbers, three for space, one for time. If those numbers for the time coordinate are identical according to the synchronization established for that FoR, then the events are simultaneous. The reason that I limited it to two is because if you have more than two, some of them can be simultaneous with each other but not with some others.
Sorry, I phrased that all wrong; I meant to talk about reference frames, not events, but I lost myself on that one.

Limiting it to two is fine, but if we limit it to two then we speak about a universe in which there are only two reference frames; if all events are simultaneous across those reference frames then absolute simultaneity prevails and not RoS; would that be correct? In saying that an event can be simultaneous in two reference frames but not with others, we are not limiting it to two, but to an undefined number of reference frames. Of course, if events are simultaneous across two refrence frames but not with other [undefined] reference frames, then RoS prevails.I presume we could build on this, saying that all events are simultaneous across three reference frames but not with [undefined] others; in that case RoS prevails again, and not absolute simultaneity.

I presume we could then extrapolate this exponentially [at least theoretically] until we arrive at a scenario where all events are simultaneous across all reference frames; in which case absolute simultaneity would prevail, wouldn't it? Would this only be possible if everything were at absolute rest, or perhaps at rest relative to each other?

In order for RoS to prevail, I presume there would only need to be one single event that isn't simultaneous across all reference frames; namely, where the time co-ordinate is different from all the rest [who have the same time co-ordinate]. Is this possible without "time" dilation?

I see Dalespam's example seems to suggest that there might, but I don't really understand the maths representing the logic.

If the two scenarios, mentioned above, are the only possibilities where absolute simultaneity could prevail, then presumably there would have to be relative motion in order for RoS to prevail; or am I way off on that?
An issue might be with the assumption I'm working from, namely, that if all events are simultaneous across all reference frames, then that is absolute simultaneity; if even one event is not simultaneous, that is RoS.EDIT: I think it is meangingful to contrast absolute simultaneity with RoS because without one there would be the other; is that accurate?
 
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  • #11
mangaroosh said:
Limiting it to two is fine, but if we limit it to two then we speak about a universe in which there are only two reference frames;
This does not make sense. The number of reference frames is not a property of a universe. Universes don't "have" reference frames, they are mathematical devices for analyzing physics, not physical features themselves. You could use an infinite number of reference frames to describe even the simplest possible universe.

If you want to talk about something "having" reference frames, then it would be an analysis which has reference frames.

mangaroosh said:
if all events are simultaneous across those reference frames then absolute simultaneity prevails and not RoS; would that be correct? In saying that an event can be simultaneous in two reference frames but not with others, we are not limiting it to two, but to an undefined number of reference frames. Of course, if events are simultaneous across two refrence frames but not with other [undefined] reference frames, then RoS prevails.I presume we could build on this, saying that all events are simultaneous across three reference frames but not with [undefined] others; in that case RoS prevails again, and not absolute simultaneity.

I presume we could then extrapolate this exponentially [at least theoretically] until we arrive at a scenario where all events are simultaneous across all reference frames; in which case absolute simultaneity would prevail, wouldn't it?
Yes to all the above.

mangaroosh said:
Would this only be possible if everything were at absolute rest, or perhaps at rest relative to each other?
No. Even if everything were at rest to each other you could still analyze it in different reference frames, and if the transformation of the time coordinate included a spatial term then there would be relativity of simultaneity.

mangaroosh said:
In order for RoS to prevail, I presume there would only need to be one single event that isn't simultaneous across all reference frames; namely, where the time co-ordinate is different from all the rest [who have the same time co-ordinate].
Strictly speaking, I don't think that is mathematically possible since coordinate systems are required to be smooth, but essentially yes.

mangaroosh said:
Is this possible without "time" dilation?
Yes, I showed an example above.

mangaroosh said:
I see Dalespam's example seems to suggest that there might, but I don't really understand the maths representing the logic.
OK, let's look at the equations [itex]t'=t-vx[/itex] and [itex]x'=x-vt[/itex] in a little more detail.

Suppose we have three events with coordinates [itex](t_A,x_A)=(0,0)[/itex], [itex](t_B,x_B)=(0,1)[/itex], and [itex](t_C,x_C)=(1,0)[/itex]. A and B are simultaneous, since [itex]t_A=t_B[/itex], and the time between A and C is 1.

Now, transforming to the primed coordinates using the above formulas (v=0.5) gives [itex](t'_A,x'_A)=(0,0)[/itex], [itex](t'_B,x'_B)=(-.5,1)[/itex], and [itex](t'_C,x'_C)=(1,-.5)[/itex]. So we see that [itex]t_A \ne t_B[/itex] meaning that simultaneity is relative, and the time between A and C is still 1 meaning that time does not dilate.

Therefore, the relativity of simultaneity is possible without time dilation.

mangaroosh said:
If the two scenarios, mentioned above, are the only possibilities where absolute simultaneity could prevail, then presumably there would have to be relative motion in order for RoS to prevail; or am I way off on that?
It doesn't have to do with motion, but with the transformation between different reference frames.

mangaroosh said:
An issue might be with the assumption I'm working from, namely, that if all events are simultaneous across all reference frames, then that is absolute simultaneity; if even one event is not simultaneous, that is RoS.

EDIT: I think it is meangingful to contrast absolute simultaneity with RoS because without one there would be the other; is that accurate?
Yes to the above, although again mathematically I don't think that it is possible for only one event to be non-simultaneous.
 
  • #12
DaleSpam said:
Now, transforming to the primed coordinates using the above formulas (v=0.5) gives [itex](t'_A,x'_A)=(0,0)[/itex], [itex](t'_B,x'_B)=(-.5,1)[/itex], and [itex](t'_C,x'_C)=(1,-.5)[/itex]. So we see that [itex]t_A \ne t_B[/itex] meaning that simultaneity is relative, and the time between A and C is still 1 meaning that time does not dilate.
What happened to gamma?

The way I calculate the three transformed events, I get:

A' = (0,0)
B' = (-0.577,1.1547)
C' = (1.1547,-0.577)

So A and C do not have the same time coordinates so they are not simultaneous.

EDIT: I see that wasn't your point. I should have said, the time between A and C is not the same as before, it's longer in the primed frame. But I wouldn't call that time dilation, it's just different coordinates for a pair of events.
 
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  • #13
ghwellsjr said:
What happened to gamma?
I was describing this transformation:
DaleSpam said:
OK, let's look at the equations [itex]t'=t-vx[/itex] and [itex]x'=x-vt[/itex] in a little more detail.
Which has no gamma. I was showing a transformation (not the Lorentz transform) which had relativity of simultaneity, but not length contraction nor time dilation. The transformation above is not a useful transform for physics, just an example showing that the relativity of simultaneity is not the same thing as length contraction and time dilation.
 
  • #14
DaleSpam said:
This does not make sense. The number of reference frames is not a property of a universe. Universes don't "have" reference frames, they are mathematical devices for analyzing physics, not physical features themselves. You could use an infinite number of reference frames to describe even the simplest possible universe.

If you want to talk about something "having" reference frames, then it would be an analysis which has reference frames.
Apologies, I am aware of that, but don't often use terminology that makes that clear.


DaleSpam said:
No. Even if everything were at rest to each other you could still analyze it in different reference frames, and if the transformation of the time coordinate included a spatial term then there would be relativity of simultaneity.
That would be another thing that I don't understand, namely how, or why, the time co-ordinate would include a spatial term.


DaleSpam said:
OK, let's look at the equations [itex]t'=t-vx[/itex] and [itex]x'=x-vt[/itex] in a little more detail.

Suppose we have three events with coordinates [itex](t_A,x_A)=(0,0)[/itex], [itex](t_B,x_B)=(0,1)[/itex], and [itex](t_C,x_C)=(1,0)[/itex]. A and B are simultaneous, since [itex]t_A=t_B[/itex], and the time between A and C is 1.

Now, transforming to the primed coordinates using the above formulas (v=0.5) gives [itex](t'_A,x'_A)=(0,0)[/itex], [itex](t'_B,x'_B)=(-.5,1)[/itex], and [itex](t'_C,x'_C)=(1,-.5)[/itex]. So we see that [itex]t_A \ne t_B[/itex] meaning that simultaneity is relative, and the time between A and C is still 1 meaning that time does not dilate.

Therefore, the relativity of simultaneity is possible without time dilation.

It doesn't have to do with motion, but with the transformation between different reference frames.

Yes to the above, although again mathematically I don't think that it is possible for only one event to be non-simultaneous.
Thanks for going through the above; the part I don't understand is the initial equations; I read [itex]t'=t-vx[/itex] as meaning [itex]t'[/itex] equals t minus the velocity along the X-axis, but I don't understand why the velocity comes into it.

and [itex]x'=x-vt[/itex] I read as [itex]x'[/itex] equals x minus the velocity multiplied by the time - which makes a bit more sense to me.

My interpretation of it would be that, if the clocks which give the time co-ordinates all ran at the same rate, then absolute simultaneity should prevail; and in order for RoS to prevail clocks would have to give different times (co-ordinates).


I suppose, essentially, where I have trouble is how we can go from the scenario where an event (or all events) are absolutely simultaneous across all reference frames, to a scenario where there is RoS. Presumably the initial scenario of absolute simultaneity would involve a transform (to affirm absolute simultaneity); I don't understand where a different transform could result in [the conclusion of] RoS if the initial transform leads to the conclusion of absolute simultaneity.


Hopefully that makes some bit of sense.
 
  • #15
mangaroosh said:
[..] Thanks for going through the above; the part I don't understand is the initial equations; I read [itex]t'=t-vx[/itex] as meaning [itex]t'[/itex] equals t minus the velocity along the X-axis, but I don't understand why the velocity comes into it.
[..]
My interpretation of it would be that, if the clocks which give the time co-ordinates all ran at the same rate, then absolute simultaneity should prevail; and in order for RoS to prevail clocks would have to give different times (co-ordinates). [..]
Just a primer: If you start with a reference clock in your hand, how would (indeed, how could!) you determine what time it is at a distance? That has little or nothing to do with clock rate.
 
  • #16
harrylin said:
Just a primer: If you start with a reference clock in your hand, how would (indeed, how could!) you determine what time it is at a distance? That has little or nothing to do with clock rate.

You probably couldn't, but the time at a distance would either be the same or it wouldn't; if it is the same [for all clocks at a distance] then absolute simultaneity prevails; if any of the clocks is different, then RoS prevails. What I'm wondering is, what would cause any of the clocks not to tell the same time?
 
  • #17
mangaroosh said:
You probably couldn't, but the time at a distance would either be the same or it wouldn't; if it is the same [for all clocks at a distance] then absolute simultaneity prevails; if any of the clocks is different, then RoS prevails. What I'm wondering is, what would cause any of the clocks not to tell the same time?
Sorry, I could not decipher your method to set a distant clock "on time", such that you assume (or pretend) that both clocks indicate the same time perfectly simultaneously, even if only shortly. How would you do that? How could you make distant clocks tell exactly the same time?
 
  • #18
harrylin said:
Sorry, I could not decipher your method to set a distant clock "on time", such that you assume (or pretend) that both clocks indicate the same time perfectly simultaneously, even if only shortly. How would you do that? How could you make distant clocks tell exactly the same time?

I mightn't be making the point very lucidly, but the intention isn't to set two distant clocks to the exact same time; the question is, how might it arise that they don't tell the exact same time?

There's only two possible scenarios: either the clocks do tell the same time, or they don't. If they do then absolute simultaneity prevails; if they don't RoS prevails; what would cause them not to tell the same time?
 
  • #19
mangaroosh said:
There's only two possible scenarios: either the clocks do tell the same time, or they don't. If they do then absolute simultaneity prevails; if they don't RoS prevails; what would cause them not to tell the same time?
We have no way of knowing if a clock remote from us has the same time on it as our local clock. That's the problem. Once you recognize that there is no test, no measurement, no way to detect, no way to determine, etc., etc., etc., the time on a remote clock, then you can follow Einstein's process. He said unless you define the time on the remote clock, it is impossible to deal with the problem. And you can define it arbitrarily in many different ways. So rather than suppose, like everyone else did, that there is an absolute universal time that nature is ticking away at, he postulated that the time on a remote clock is equal to the time on a local clock when a light signal takes the same amount of time to get from the local clock to the remote clock as it does for a light signal to get from the remote clock to the local clock. Under this defintion, RoS prevails. Under the previous assumption of an absolute universal time, RoS is not a factor.
 
  • #20
mangaroosh said:
I mightn't be making the point very lucidly, but the intention isn't to set two distant clocks to the exact same time; the question is, how might it arise that they don't tell the exact same time?

There's only two possible scenarios: either the clocks do tell the same time, or they don't. If they do then absolute simultaneity prevails; if they don't RoS prevails; what would cause them not to tell the same time?
We understood your intention, which appears to be based on an unfounded assumption. Clocks are man-made and when you put a battery in it you can set it at any time you want. Thus, in order to have two clocks tell the same time, you have to do that.

You seem to have already a difficulty with getting two distant clocks synchronized according to yourself, despite your suggestion that all clocks will be automatically synchronized with all other clocks according to everyone. Nevertheless it was only an introduction to the next question: how can you do that in such a way that everyone will agree?
 
  • #21
ghwellsjr said:
We have no way of knowing if a clock remote from us has the same time on it as our local clock. That's the problem. Once you recognize that there is no test, no measurement, no way to detect, no way to determine, etc., etc., etc., the time on a remote clock, then you can follow Einstein's process. He said unless you define the time on the remote clock, it is impossible to deal with the problem. And you can define it arbitrarily in many different ways. So rather than suppose, like everyone else did, that there is an absolute universal time that nature is ticking away at, he postulated that the time on a remote clock is equal to the time on a local clock when a light signal takes the same amount of time to get from the local clock to the remote clock as it does for a light signal to get from the remote clock to the local clock. Under this defintion, RoS prevails. Under the previous assumption of an absolute universal time, RoS is not a factor.

harrylin said:
We understood your intention, which appears to be based on an unfounded assumption. Clocks are man-made and when you put a battery in it you can set it at any time you want. Thus, in order to have two clocks tell the same time, you have to do that.

You seem to have already a difficulty with getting two distant clocks synchronized according to yourself, despite your suggestion that all clocks will be automatically synchronized with all other clocks according to everyone. Nevertheless it was only an introduction to the next question: how can you do that in such a way that everyone will agree?

Thanks guys; it hasn't clicked for me yet. It might be easier for me to outline the question by contrasting Einsteinian relativity with Lorentzian relativity; under Lorentzian relativity there is absolute simultaneity, while under Einsteinian relativity there is RoS. If both theories are indistinguishable in terms of experimental data, why is it that there is RoS in one and absolute simultaneity in the other, if both theories include clocks which tick at different rates?
 
  • #22
mangaroosh said:
Thanks guys; it hasn't clicked for me yet. It might be easier for me to outline the question by contrasting Einsteinian relativity with Lorentzian relativity; under Lorentzian relativity there is absolute simultaneity, while under Einsteinian relativity there is RoS. If both theories are indistinguishable in terms of experimental data, why is it that there is RoS in one and absolute simultaneity in the other, if both theories include clocks which tick at different rates?
Only because LET believers believe it is so. Or maybe I should say "believed" it was so because I don't think there are any LET believers left in the world.
 
  • #23
ghwellsjr said:
Only because LET believers believe it is so. Or maybe I should say "believed" it was so because I don't think there are any LET believers left in the world.
Would it not be more accurate to say that the theory postulates it? If there were no theory, there would be nothing to believe.
 
  • #24
I don't think it takes a formal theory to believe that time is absolute, that just seems natural and normal, don't you think? But once you measure the speed of light to be constant, it's only natural and normal to come up with a theory that retains absolute time, don't you think?
 
  • #25
ghwellsjr said:
I don't think it takes a formal theory to believe that time is absolute, that just seems natural and normal, don't you think? But once you measure the speed of light to be constant, it's only natural and normal to come up with a theory that retains absolute time, don't you think?
I'd agree, it doesn't take a formal theory to believe that time is absolute, but LET appears to postulate absolute simultaneity, and if the experimental evidence doesn't distinguish between it and SR then there must be a reason why RoS prevails in SR but not LET. I'm just trying to understand what that reason is.

In the last sentence, do you mean, once you measure the speed of light to be constant, it's only natural and normal to come up with a theory abandons absolute time?
 
  • #26
mangaroosh said:
I'd agree, it doesn't take a formal theory to believe that time is absolute, but LET appears to postulate absolute simultaneity, and if the experimental evidence doesn't distinguish between it and SR then there must be a reason why RoS prevails in SR but not LET. I'm just trying to understand what that reason is.
I think I've asked you before--do you think if no one else had put forward the idea that time could be relative, that is, time actually progresses at different rates under different conditions, you would ever come up with that idea on your own? Even now, many people struggle with this concept even though the idea is so prevalent in our world at this time.
mangaroosh said:
In the last sentence, do you mean, once you measure the speed of light to be constant, it's only natural and normal to come up with a theory abandons absolute time?
I only meant that just because the speed of light was measured to be constant, why should anyone connect that with time being relative? Wouldn't you do what the LET scientists did and say that the clocks moving in the ether run slow for some mechanical reason rather than say that time itself was slowing down for them? It made perfect sense that light propagated at a constant speed with respect to the ether and they just couldn't detect that fact rather than claim that light propagated at a constant speed for each inertial state.
 
  • #27
ghwellsjr said:
I think I've asked you before--do you think if no one else had put forward the idea that time could be relative, that is, time actually progresses at different rates under different conditions, you would ever come up with that idea on your own? Even now, many people struggle with this concept even though the idea is so prevalent in our world at this time.
That's a philosophical question without an answer I would say; history might show that no one but Einstein could have come up with the idea, but if you or I had been born in his stead and had his life experiences, we both would have come up with it.

ghwellsjr said:
I only meant that just because the speed of light was measured to be constant, why should anyone connect that with time being relative? Wouldn't you do what the LET scientists did and say that the clocks moving in the ether run slow for some mechanical reason rather than say that time itself was slowing down for them? It made perfect sense that light propagated at a constant speed with respect to the ether and they just couldn't detect that fact rather than claim that light propagated at a constant speed for each inertial state.
Those appear to be two differing interpretations, both equally supported by evidence; is that a fair enough comment?

According LET clocks tick at different rates for mechanical reasons, and so absolute simultaneity prevails.

According to Einsteinian relativity, clocks tick at different rates becuse "time itself slows down"; is it because "time itself slows down" in certain reference frames that RoS prevails? I presume it must be, because if time didn't slow down, and slower ticking clocks were the result of the mechanics of the clock then, as per LET, absolute simultaneity would prevail. Alternatively, if time itself didn't slow down and clocks all ticked at the same rate, then absolute simultaneity would prevail.
 
  • #28
mangaroosh said:
Thanks guys; it hasn't clicked for me yet. It might be easier for me to outline the question by contrasting Einsteinian relativity with Lorentzian relativity; under Lorentzian relativity there is absolute simultaneity, while under Einsteinian relativity there is RoS. If both theories are indistinguishable in terms of experimental data, why is it that there is RoS in one and absolute simultaneity in the other, if both theories include clocks which tick at different rates?
In Lorentzian relativity there is absolute simultaneity that cannot be measured, as well as "local time". Poincare pointed out that clocks measure local time. This local time already had the characteristic of relativity of simultaneity before relativity, but until 1904 it was only approximate. Einsteinian relativity considers only what can be measured; consequently he calls "local time" simply "time".

A similar thing happened earlier in classical mechanics: Newtonian mechanics distinguishes absolute velocity that cannot be measured as well as relative velocity that can be measured. Classical mechanics only deals with relative velocity.
 
  • #29
harrylin said:
In Lorentzian relativity there is absolute simultaneity that cannot be measured, as well as "local time". Poincare pointed out that clocks measure local time. This local time already had the characteristic of relativity of simultaneity before relativity, but until 1904 it was only approximate. Einsteinian relativity considers only what can be measured; consequently he calls "local time" simply "time".
That's fair enough; but if all the local clocks registered the same time then absolute simultaneity would prevail; but local clocks register different times and so RoS prevails. Why do local clocks not register the same time?


harrylin said:
A similar thing happened earlier in classical mechanics: Newtonian mechanics distinguishes absolute velocity that cannot be measured as well as relative velocity that can be measured. Classical mechanics only deals with relative velocity.
At the risk of going off-topic, I think the idea of measuring absolute velocity is somewhat of a misnomer, because measurement is, by it's very nature, relative i.e. it is making a statement about one phenomenon by relating it to other phenomena.

Absolute velocity is a simple yes or no answer to the question, is there velocity?
 
  • #30
mangaroosh said:
ghwellsjr said:
I only meant that just because the speed of light was measured to be constant, why should anyone connect that with time being relative? Wouldn't you do what the LET scientists did and say that the clocks moving in the ether run slow for some mechanical reason rather than say that time itself was slowing down for them? It made perfect sense that light propagated at a constant speed with respect to the ether and they just couldn't detect that fact rather than claim that light propagated at a constant speed for each inertial state.
Those appear to be two differing interpretations, both equally supported by evidence; is that a fair enough comment?
Yes.
mangaroosh said:
According LET clocks tick at different rates for mechanical reasons, and so absolute simultaneity prevails.

According to Einsteinian relativity, clocks tick at different rates becuse "time itself slows down"; is it because "time itself slows down" in certain reference frames that RoS prevails? I presume it must be, because if time didn't slow down, and slower ticking clocks were the result of the mechanics of the clock then, as per LET, absolute simultaneity would prevail. Alternatively, if time itself didn't slow down and clocks all ticked at the same rate, then absolute simultaneity would prevail.
Let me try it this way:

I'm going to stipulate, for the sake of argument, that LET is the correct understanding of the way nature works. That means that there truly is an immovable ether and light propagates at c only with respect to the rest state of that ether. Time and space are absolutes. And because of the mechanical properties of the ether and the way that matter interacts with it, when matter moves through the ether, it contracts along the direction of motion. Also, any physical clock made of matter will keep track of the absolute time correctly only if it is stationary in the ether. If it is moving, the operation of the clock makes it slow down and so it is no longer keeping the correct time. The Lorentz factor correctly describes how much a moving clock slows down and how physical objects are contracted along the direction of motion. This is the stipulated truth about nature.

Now let's suppose an observer who is stationary in that ether has some measuring rods and some accurate, stable clocks and a mirror. When he attempts to measure the round trip speed of light, he gets the correct answer because his rulers and clocks are normal since they are not moving. Now let's suppose that he gets in a spaceship and accelerates to a high rate of speed with respect to the ether. This will cause his clocks to slow down and his rulers to contract when aligned with the direction of motion. When he repeats his measurement of the speed of light, what will happen? Well we know if he aligns his experiment so that the light has to travel against the ether to get to the mirror, it will take longer than when he was stationary. After it hits the mirror and reflects back, we know that it will take a shorter time than before because it is being carried along by the ether. Furthermore, we know that when he measures the distance between the mirrors, they will be closer together. As long as his clocks and rulers are modified by just the right amount, he will get the same measurement of the speed of light as he did before. But we know why he gets the same answer and that's because of length contraction and time dilation for matter moving through the ether.

As a matter of fact, the moving observer will see everything exactly the same when he is moving as he did when he was stationary. He cannot tell that he is moving with repsect to the ether. Do you understand this?
 
  • #31
mangaroosh said:
That's fair enough; but if all the local clocks registered the same time then absolute simultaneity would prevail; but local clocks register different times and so RoS prevails. Why do local clocks not register the same time?
Originally (before SR) this was for practical reasons as you can read here:
http://en.wikisource.org/wiki/The_Measure_of_Time
It was found that even if we wanted to, we cannot detect absolute simultaneity. But if we wanted, we could define a truly "universal time" and synchronize all clocks accordingly.
At the risk of going off-topic, I think the idea of measuring absolute velocity is somewhat of a misnomer, because measurement is, by it's very nature, relative i.e. it is making a statement about one phenomenon by relating it to other phenomena. [...]
Apparently Newton defined it to mean velocity relative to absolute space; it doesn't mean "absolute" in the secondary meaning that you think (and which probably resulted from it much later).
- http://gravitee.tripod.com/definitions.htm
(press "cancel" and scroll to "SCHOLIUM")

Harald
 
  • #32
ghwellsjr said:
Yes.

Let me try it this way:

I'm going to stipulate, for the sake of argument, that LET is the correct understanding of the way nature works. That means that there truly is an immovable ether and light propagates at c only with respect to the rest state of that ether. Time and space are absolutes. And because of the mechanical properties of the ether and the way that matter interacts with it, when matter moves through the ether, it contracts along the direction of motion. Also, any physical clock made of matter will keep track of the absolute time correctly only if it is stationary in the ether. If it is moving, the operation of the clock makes it slow down and so it is no longer keeping the correct time. The Lorentz factor correctly describes how much a moving clock slows down and how physical objects are contracted along the direction of motion. This is the stipulated truth about nature.

Now let's suppose an observer who is stationary in that ether has some measuring rods and some accurate, stable clocks and a mirror. When he attempts to measure the round trip speed of light, he gets the correct answer because his rulers and clocks are normal since they are not moving. Now let's suppose that he gets in a spaceship and accelerates to a high rate of speed with respect to the ether. This will cause his clocks to slow down and his rulers to contract when aligned with the direction of motion. When he repeats his measurement of the speed of light, what will happen? Well we know if he aligns his experiment so that the light has to travel against the ether to get to the mirror, it will take longer than when he was stationary. After it hits the mirror and reflects back, we know that it will take a shorter time than before because it is being carried along by the ether. Furthermore, we know that when he measures the distance between the mirrors, they will be closer together. As long as his clocks and rulers are modified by just the right amount, he will get the same measurement of the speed of light as he did before. But we know why he gets the same answer and that's because of length contraction and time dilation for matter moving through the ether.

As a matter of fact, the moving observer will see everything exactly the same when he is moving as he did when he was stationary. He cannot tell that he is moving with repsect to the ether. Do you understand this?
Sorry gh, it might be the way I'm phrasing the question; I understand the above (I think), but it isn't Lorentzian relativity I'm wondering about, it's RoS in Einsteinian relativity.

My understanding is that RoS prevails, or perhaps more accurately, RoS is a consequence of the fact that [local*] clocks tick at different rates - if they didn't then absolute simultaneity would prevail. According to LET, as you have outlined above, clocks slow down for mechanical reasons (presumably this is true even when LET is stripped of everything but the absolute rest frame). That much I understand.

The question pertains to Einsteinian relativity. My understanding is that RoS is what results when [local*] clocks tick at different rates - is that much correct? As mentioned, LET postulates that this is down to the mechanics of the clock (as outlined above) - what, according to Einsteinian relativity, is the reason that [local*] clocks tick at different rates?*Just in case the term "local" isn't used in Einsteinian relativity, what I mean is the clock at rest in a given FoR
 
  • #33
mangaroosh said:
Sorry gh, it might be the way I'm phrasing the question; I understand the above (I think), but it isn't Lorentzian relativity I'm wondering about, it's RoS in Einsteinian relativity.

My understanding is that RoS prevails, or perhaps more accurately, RoS is a consequence of the fact that [local*] clocks tick at different rates - if they didn't then absolute simultaneity would prevail. According to LET, as you have outlined above, clocks slow down for mechanical reasons (presumably this is true even when LET is stripped of everything but the absolute rest frame). That much I understand.

The question pertains to Einsteinian relativity. My understanding is that RoS is what results when [local*] clocks tick at different rates - is that much correct? As mentioned, LET postulates that this is down to the mechanics of the clock (as outlined above) - what, according to Einsteinian relativity, is the reason that [local*] clocks tick at different rates?


*Just in case the term "local" isn't used in Einsteinian relativity, what I mean is the clock at rest in a given FoR
The second postulate: that light propagates in both directions at the same speed of a round-trip measurement of its speed, is what results in RoS for SR. LET does not have that postulate. Instead, it claims that the one-way speed of light is constant only in the absolute ether.

The one-way speed of light cannot be observed and cannot be measured. That is why we are free to make any postulate regarding it. For example, let's say that we place a mirror 10 feet away from our light source and our timer. We turn on the light at the exact moment we start the timer. When we detect the reflected light and stop the timer it reads 20 nanoseconds. We have the option of dividing the times for the two trips any way we want. We can say that it took 0 time for the light to get to the mirror and 20 nanoseconds to get back or vice versa. Or we could say that it took 1 nanosecond to get to the mirror and 19 nanoseconds to get back. Or 2 and 18, 3 and 17, etc. Or we could say, like LET that we have to determine the division of the times based on how fast we think we are traveling with respect to ether when the round-trip measurement assigns the times as equal. That claim supports the idea of an absolute time. Or we could say, like SR, that those times are equal every time we make the measurement which leads to the concept of relative time which is just another way of saying Relativity of Simultaneity.

Please look again at Einstein's 1905 paper introducing Special Relativity. Look at the title of the first section. It's called "Definition of Simultaneity". Look at what he says in the third paragraph:

We have to take into account that all our judgments in which time plays a part are always judgments of simultaneous events. If, for instance, I say, “That train arrives here at 7 o'clock,” I mean something like this: “The pointing of the small hand of my watch to 7 and the arrival of the train are simultaneous events.”

Then read the rest of that section and see how he builds up a consistent definition of time in remote locations.

Please study the first half, Part I, of his paper. If you don't understand something there, please ask a question. You need to understand Einstein's presentation if you want to understand Einsteinian relativity. I don't want to entertain any more questions that aren't sourced from Einstein.
 
Last edited:
  • #34
mangaroosh said:
[..] My understanding is that RoS prevails, or perhaps more accurately, RoS is a consequence of the fact that [local*] clocks tick at different rates - if they didn't then absolute simultaneity would prevail. [..] The question pertains to Einsteinian relativity. My understanding is that RoS is what results when [local*] clocks tick at different rates - is that much correct? [..]
That is wrong, as demonstrated in the reference of post #31 (in the second half of that reference). RoS was already applied without accounting for time dilation. And also the "Voigt transformation" (although he didn't intend it that way) doesn't have time dilation.

In order to obtain the Lorentz transformations from the Galilean transformations, one has to assume time dilation and Lorentz contraction (done by nature) as well as RoS (should be done by the experimentalist, by means of clock synchronization).

Harald
 
  • #35
ghwellsjr said:
The second postulate: that light propagates in both directions at the same speed of a round-trip measurement of its speed, is what results in RoS for SR. LET does not have that postulate. Instead, it claims that the one-way speed of light is constant only in the absolute ether.

The one-way speed of light cannot be observed and cannot be measured. That is why we are free to make any postulate regarding it. For example, let's say that we place a mirror 10 feet away from our light source and our timer. We turn on the light at the exact moment we start the timer. When we detect the reflected light and stop the timer it reads 20 nanoseconds. We have the option of dividing the times for the two trips any way we want. We can say that it took 0 time for the light to get to the mirror and 20 nanoseconds to get back or vice versa. Or we could say that it took 1 nanosecond to get to the mirror and 19 nanoseconds to get back. Or 2 and 18, 3 and 17, etc. Or we could say, like LET that we have to determine the division of the times based on how fast we think we are traveling with respect to ether when the round-trip measurement assigns the times as equal. That claim supports the idea of an absolute time. Or we could say, like SR, that those times are equal every time we make the measurement which leads to the concept of relative time which is just another way of saying Relativity of Simultaneity.

Please look again at Einstein's 1905 paper introducing Special Relativity. Look at the title of the first section. It's called "Definition of Simultaneity". Look at what he says in the third paragraph:

We have to take into account that all our judgments in which time plays a part are always judgments of simultaneous events. If, for instance, I say, “That train arrives here at 7 o'clock,” I mean something like this: “The pointing of the small hand of my watch to 7 and the arrival of the train are simultaneous events.”

Then read the rest of that section and see how he builds up a consistent definition of time in remote locations.

Please study the first half, Part I, of his paper. If you don't understand something there, please ask a question. You need to understand Einstein's presentation if you want to understand Einsteinian relativity. I don't want to entertain any more questions that aren't sourced from Einstein.
thanks gh, I'll have a look at Einstein's paper and try to base my questions on Einstein's paper.


Just one quick question though, to see if I am even in the ball park with understanding this: am I at least [some way] right in thinking that if all clocks ticked at the same rate then absolute simultaneity would prevail; but because clocks tick at different rates RoS prevails?
 
<h2>What is the theory of relativity?</h2><p>The theory of relativity is a fundamental concept in physics that explains how the laws of physics are the same for all observers in uniform motion. It is divided into two parts: special relativity, which deals with objects moving at constant speeds, and general relativity, which deals with objects in accelerated motion or in the presence of gravity.</p><h2>What is the relativity of simultaneity?</h2><p>The relativity of simultaneity is a concept in special relativity that states that the perception of simultaneity (two events happening at the same time) is relative to the observer's frame of reference. In other words, two events that appear simultaneous to one observer may not appear simultaneous to another observer in a different frame of reference.</p><h2>How does the relativity of simultaneity affect the measurement of time?</h2><p>The relativity of simultaneity has a significant impact on the measurement of time. In special relativity, time is not absolute and is relative to the observer's frame of reference. This means that two observers moving at different speeds may measure different amounts of time for the same event. This effect becomes more pronounced as the speed of the observers approaches the speed of light.</p><h2>What is the thought experiment used to explain the relativity of simultaneity?</h2><p>The most famous thought experiment used to explain the relativity of simultaneity is the "train and platform" scenario. In this experiment, two observers on a moving train and on a stationary platform observe a lightning strike at the same time. However, due to the relativity of simultaneity, the observers will perceive the lightning strike at different times.</p><h2>What are some real-world applications of the relativity of simultaneity?</h2><p>The relativity of simultaneity has many real-world applications, particularly in the fields of physics and engineering. For example, it is essential to consider the relativity of simultaneity when synchronizing clocks in GPS satellites to ensure accurate navigation. It also plays a crucial role in understanding the behavior of particles in particle accelerators and the effects of time dilation in space travel.</p>

What is the theory of relativity?

The theory of relativity is a fundamental concept in physics that explains how the laws of physics are the same for all observers in uniform motion. It is divided into two parts: special relativity, which deals with objects moving at constant speeds, and general relativity, which deals with objects in accelerated motion or in the presence of gravity.

What is the relativity of simultaneity?

The relativity of simultaneity is a concept in special relativity that states that the perception of simultaneity (two events happening at the same time) is relative to the observer's frame of reference. In other words, two events that appear simultaneous to one observer may not appear simultaneous to another observer in a different frame of reference.

How does the relativity of simultaneity affect the measurement of time?

The relativity of simultaneity has a significant impact on the measurement of time. In special relativity, time is not absolute and is relative to the observer's frame of reference. This means that two observers moving at different speeds may measure different amounts of time for the same event. This effect becomes more pronounced as the speed of the observers approaches the speed of light.

What is the thought experiment used to explain the relativity of simultaneity?

The most famous thought experiment used to explain the relativity of simultaneity is the "train and platform" scenario. In this experiment, two observers on a moving train and on a stationary platform observe a lightning strike at the same time. However, due to the relativity of simultaneity, the observers will perceive the lightning strike at different times.

What are some real-world applications of the relativity of simultaneity?

The relativity of simultaneity has many real-world applications, particularly in the fields of physics and engineering. For example, it is essential to consider the relativity of simultaneity when synchronizing clocks in GPS satellites to ensure accurate navigation. It also plays a crucial role in understanding the behavior of particles in particle accelerators and the effects of time dilation in space travel.

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