A question about the equivalence principle.

In summary: The discrepancy between the clock rates at the front and the rear of the rocket is a measure of time dilation.Yes.
  • #71
yuiop said:
The snag is that the by calculating the relative time dilation by using the relative velocities at the front and back of the rocket one comes to the conclusion that the relative rates of clocks on board the rocket as measured by observers on board the rocket increases over time which is simply not true. The relative rates of clocks on board the rocket as measured by observers on board the rocket is constant over time.

Hi yuiop you have returned ;-)

i agree with your assumption that it appears that the relative dilation due to coordinate velocity would increase. That was my intuition also but after thought i became less sure.
That was partly my interest in the analysis I described.

But if we are right and the dilation differential would increase up the velocity curve this would seem to present a major problem.

As I said, the two clocks in question could be unconnected.
Independently accelerating clocks that would maintain the proper contracted separation simply as a consequence of the acceleration differential.

It seems clear that the fundamental SR principles must pertain.I.e. The gamma relation between velocity and proper time rates and deltas. And the clock hypothesis.

So any short interval measurements of coordinate velocity and clock comparisons for those intervals must correspond to the fundamental relationship where ever they taken along the course of acceleration.

Simply connecting the two clocks into a single system should not have any effect on this relationship.

So if the results predicted by the Rindler coordinates do not agree with the results predicted by the fundamental principles of SR there would be a real question.

What possible physics would account for this ?

i.e. what would prevent the velocity dilation from occurring?

Which prediction should be considered valid?

Would you agree there would be a question?

It was actually this question which prompted my primitive attempt at calculating the dilation factor I posted earlier.

austin0 said:
But what I don't understand is why the simultaneity relative to the MCIRF's would be relevant to the accelerating system?

You missed this one. regarding Steve's derivative approach.

So have you calculated the differential due to velocity actually/ or is it just a logical guess? ;-0
thanks
 
Physics news on Phys.org
  • #72
yuiop said:
The apparent field inside an accelerating rocket also gets weaker at greater distance from the apparent source. Accelerometers attached to the nose of the rocket indicate less proper acceleration than accelerometers attached to the tail of the rocket. [..]
Good one! Yes, there is a very slight difference due to length contraction - and it's always the same for a given distance between clocks and given acceleration. However, if one allows the Earth sensor to free-fall inside or next to the rocket, it can detect no gradient at all, not even in principle.
And I now wonder if one would nevertheless interpret the (incredibly small) difference in accelerometer readings as due to a real field, with what distance to the gravitation source that would correspond, and with what mass - could one really be fooled?
 
Last edited:
  • #73
Austin0 said:
So have you calculated the differential due to velocity actually/ or is it just a logical guess? ;-0
At the time it was a estimate, but I have now done the calculations just to check and can confirm that clock speed differential between front and back increases over time if we use the velocity time dilation approach. For example if we have a constant proper acceleration of 1 at the back of the rocket and 0.1 at the front and use units of c=1, then initially the time dilation ratio (back/front) is 1 at time t=0, 0.71 at t=1 and 0.456 at t=2. This is not what would be observed on board the rocket(s) because the time (t) here is the simultaneous coordinate time in the launch frame and the notion of what is simultaneous is different on board the rocket(s). This is the crux of the matter that I shall come back to.
Austin0 said:
i agree with your assumption that it appears that the relative dilation due to coordinate velocity would increase. That was my intuition also but after thought i became less sure.
After doing the calculations I am now sure that is what would be observed as coordinate velocity increases relative to any given MCIRF, as measured relative to the simultaneous coordinate time in that given MCIRF. As above, it is the notion of simultaneity that is important and this changes with reference frames and you have not been careful to specify one.
Austin0 said:
That was partly my interest in the analysis I described.

But if we are right and the dilation differential would increase up the velocity curve this would seem to present a major problem.
We are right but it does not present a problem ;)
Austin0 said:
As I said, the two clocks in question could be unconnected.
Independently accelerating clocks that would maintain the proper contracted separation simply as a consequence of the acceleration differential.
Agree.
Austin0 said:
It seems clear that the fundamental SR principles must pertain.I.e. The gamma relation between velocity and proper time rates and deltas. And the clock hypothesis.
Agree, these fundamental SR principles do hold.
Austin0 said:
So if the results predicted by the Rindler coordinates do not agree with the results predicted by the fundamental principles of SR there would be a real question.

What possible physics would account for this ?

i.e. what would prevent the velocity dilation from occurring?
Nothing. Velocity time dilation still occurs, but the effect cancels out. Consider two signals emitted simultaneously from the front and back of a rocket at coordinate time t=0 as measured in a given MCIRF. To give this MCIRF a label I will call it the launch frame (LF), but there is nothing special about this MCIRF and I could do an identical analysis in any other MCIRF. When the signal from the front arrives at the back let us say the velocity in the LF is vb and when the signal from the back arrives at the front, the velocity in the LF is vf. It turns out that with Born rigid acceleration, vb = vf. This means that sqrt(1-(vb)^2) = sqrt(1-(vf)^2) so at the time of the reception of the signals the velocities and velocity based time dilation is identical at back and front and so there is no differential time dialtion between back and front due to velocity time dilation. All the apparent differential time dilation observed on board the rocket is due to classical Doppler shift according to the observer in the inertial LF.
Austin0 said:
Which prediction should be considered valid?
They are both valid. One is the interpretation according to the simultaneity of an inertial reference frame and the other is the interpretation due to a different notion of simultaneity in an accelerating reference frame.
Austin0 said:
Would you agree there would be a question?
Not really. We are used to observer dependent quantities such as coordinate velocity, time, distance, time dilation, length contraction, simultaneity etc. being different in different inertial reference frame (by definition) in regular unaccelerated SR.
Austin0 said:
You missed this one. regarding Steve's derivative approach: "But what I don't understand is why the simultaneity relative to the MCIRF's would be relevant to the accelerating system?"
Well now we are back to the crux of the problem. I have been putting this off because while I feel I understand it intuitively in my head, putting it into words is not so easy :) The first difficulty is how to define a notion of simultaneity for the observers on board the rocket, when there own reference clocks appear to be running at different rates in different locations on board the rocket. If we ask the observers at the front and back of the rocket to send signals simultaneously in there own reference frame, how are they going to arrange that? One way to do this would be to agree a convention that defines "simultaneous" events at the front and back of the rocket as being events that are both simultaneous in a shared MCIRF. If they do this they will observe that the signals are received at the back and front "simultaneously" because the reception events will be simultaneous in a shared MCIRF, (but this shared MCIRF will not be the same shared MCIRF that the signals were emitted simultaneously in). For a practical example, let's say we an inertial rocket ir1 moving at 0.6c and another ir2 moving at 0.8c both relative to the LF. After launch we tell the observers at the front and back to send a signal at the moment they are at rest with ir1, then for a suitable length accelerating rocket, they will both receive signals when they are momentarily at rest with ir2. You might argue that I have cheated here, because I have simply defined, rather than derived a notion of simultaneous for the accelerating rocket observers.

Another approach is to speed up the rear clock (as mentioned in an earlier post) so that it appears to be running at the same rate as the front clock. Now we have an unequivocal method of defining simultaneous in the accelerating rocket reference frame and can synchronise clocks using the usual Einstein clock synchronisation convention. Now when we send signals from the front and back using the on board rocket reference clocks, the signals arrive simultaneously at the back and front respectively according to the rocket clocks and the elapsed time between sending and receiving is equal according to both the front and back accelerating rocket observers. At no point here have we had to refer to the MCIRF's but if we compare results, simultaneous emission and simultaneous reception of signals as measured by the accelerating rocket observers, agrees with simultaneous as measured in the MCIRF's. Now the rocket observers know they had to speed up the rear clock to make it run at the same rate as the front clock so they know the real proper time rate of the rear clock must be slower than the proper time rate of the front clock. If they consider themselves to be stationary in their own reference frame they would ascribe this differential clock rate to a gravitational field and this coincides with the proper acceleration they can feel and and measure. The observers in a given inertial reference frame outside the rocket would ascribe the differential clock rates observed by the rocket observers to classical Doppler shift.

harrylin said:
Good one! Yes, there is a very slight difference due to length contraction - and it's always the same for a given distance between clocks and given acceleration. However, if one allows the Earth sensor to free-fall inside or next to the rocket, it can detect no gradient at all, not even in principle.
And I now wonder if one would nevertheless interpret the (incredibly small) difference in accelerometer readings as due to a real field, with what distance to the gravitation source that would correspond, and with what mass - could one really be fooled?

The differences between the Born rigid accelerating rocket and a real gravitational field, due to tidal effects, are significant enough, that we would be only be fooled if limited to measurements in a very restricted local region.
 
Last edited:
  • #74
Austin0 said:
But what I don't understand is why the simultaneity relative to the MCIRF's would be relevant to the accelerating system?

I'm not sure I understand your question. You're asking why the inertial coordinate system is relevant to the accelerated observer? In some ways, it's just a matter of convention for what the accelerated observer considers two "simultaneous" events. One convention is to use the same notion of simultaneity as a comoving inertial observer.

I would think that given the proper acceleration values for front and back for the initial length , that simply calculating velocities from coordinate acceleration would give relative gamma between the front and back directly.

No, that's not correct. If you wait a short time δt after launch, the rear clock will be traveling at speed vrear = grear δt, and the front clock will be traveling at speed vfront = gfront δt. So just based on that, you would expect a relative rate of the clocks to be
√(1- (grear δt)2/c2))/√(1- (gfront δt)2/c2))
but the actual ratio of rates is
gfront /grear
those aren't close at all. The first goes to 1 as δt → 0, but the second doesn't.
 
  • #75
stevendaryl said:
No, that's not correct. If you wait a short time δt after launch, the rear clock will be traveling at speed vrear = grear δt, and the front clock will be traveling at speed vfront = gfront δt. So just based on that, you would expect a relative rate of the clocks to be
√(1- (grear δt)2/c2))/√(1- (gfront δt)2/c2))
but the actual ratio of rates is
gfront /grear
those aren't close at all. The first goes to 1 as δt → 0, but the second doesn't.

I haven't been following this thread closely, and I can see a lot of formulas have been written down that I have not looked at in detail, but this doesn't look right; the ratio of clock rates *should* be governed by the first formula, based on the two velocities. The ratio of clock rates is certainly *not* equal to the ratio of accelerations. And the ratio *should* go to 1 as delta t -> 0, because at launch, which is what delta t -> 0 means, the two clocks are at rest relative to each other, so their clock rates are the same.

Some web pages that seem to me to be relevant are Greg Egan's page on the Rindler horizon:

http://gregegan.customer.netspace.net.au/SCIENCE/Rindler/RindlerHorizon.html

And the Usenet Physics FAQ pages on SR and acceleration (which links to the page on the relativistic rocket equation, another good resource), and on the clock hypothesis:

http://math.ucr.edu/home/baez/physics/Relativity/SR/acceleration.html

http://math.ucr.edu/home/baez/physics/Relativity/SR/clock.html
 
  • #76
PeterDonis said:
I haven't been following this thread closely, and I can see a lot of formulas have been written down that I have not looked at in detail, but this doesn't look right; the ratio of clock rates *should* be governed by the first formula, based on the two velocities. The ratio of clock rates is certainly *not* equal to the ratio of accelerations. And the ratio *should* go to 1 as delta t -> 0, because at launch, which is what delta t -> 0 means, the two clocks are at rest relative to each other, so their clock rates are the same.

But that doesn't give the correct answer, which is that, according to measurements performed by observers aboard the rocket, the front clock always runs faster than the rear clock, the ratio of their rates is always the same: 1 + gL/c2.
 
  • #77
stevendaryl said:
But that doesn't give the correct answer, which is that, according to measurements performed by observers aboard the rocket, the front clock always runs faster than the rear clock, the ratio of their rates is always the same: 1 + gL/c2.

It's possible that I'm misunderstanding the scenario you are talking about. When you say that a short time after launch, each clock will be traveling at a velocity g delta t, where g is the acceleration of the clock, that tells me that exactly at time t = 0, i.e., before the time delta t elapses, each clock is at rest in the same "launch frame". If the two clocks are at rest relative to each other at some instant, then their clock rates, at that instant, are the same. See the web page I linked to on the clock postulate. My understanding is that that is the scenario you are talking about.

The formula 1 + gL/c describes something a bit different than what I would call the "ratio of instantaneous clock rates", but I'd rather not get into that until I'm sure I correctly understand the scenario you're talking about.
 
  • #78
PeterDonis said:
It's possible that I'm misunderstanding the scenario you are talking about. When you say that a short time after launch, each clock will be traveling at a velocity g delta t, where g is the acceleration of the clock, that tells me that exactly at time t = 0, i.e., before the time delta t elapses, each clock is at rest in the same "launch frame". If the two clocks are at rest relative to each other at some instant, then their clock rates, at that instant, are the same.

To talk about clock "rates", you have to refer to two different points in time. To talk about the relative rates of two clocks, you need 4 events, and you need a notion of simultaneity.

e1 = the rear clock shows time 0.
Let F = the instantaneous rest frame of the rear clock at this event.

e2 = some event at the front clock that is simultaneous with e1 in frame F . Let T2 = the time showing on the front clock at event e2.

e3 = the rear clock shows time δT
Let F' be the instantaneous rest frame of the rear clock at this event.

e4 = some event at the front clock that is simultaneous with e3 in frame F'. Let T4 = the time showing on the front clock at event e4.

So from the point of view of an observer in the rear of the rocket, the rear clock advanced by δT, and the front clock advanced by: T4 - T2

Then the ratio of clock rates, as measured by the rear clock is:

Rfront/Rrear
= (T4 - T2)/δT

As δT → 0, this ratio does not go to 1, but goes to 1 + gL/c2, where L is the length of the rocket, and g is the acceleration of the rear.
 
  • #79
stevendaryl said:
To talk about clock "rates", you have to refer to two different points in time. To talk about the relative rates of two clocks, you need 4 events, and you need a notion of simultaneity.

I agree with the second sentence given the first. I take the first as your definition of how you are using the term "clock rate"; it is not the only possible definition, but I have no problem using yours for this discussion.

stevendaryl said:
e1 = the rear clock shows time 0.
Let F = the instantaneous rest frame of the rear clock at this event.

e2 = some event at the front clock that is simultaneous with e1 in frame F . Let T2 = the time showing on the front clock at event e2.

You've left out a key piece of information here: is the front clock at rest, in frame F, at event e2? (By hypothesis the rear clock is at rest in frame F at event e1.)

stevendaryl said:
e3 = the rear clock shows time δT
Let F' be the instantaneous rest frame of the rear clock at this event.

e4 = some event at the front clock that is simultaneous with e3 in frame F'. Let T4 = the time showing on the front clock at event e4.

Same question here. I ask these, again, to make sure I understand the scenario you are talking about. I think the answer to both is "yes", but I would really like confirmation before going into details, since there's no point in my talking about a different scenario than you are talking about.
 
  • #80
PeterDonis said:
I agree with the second sentence given the first. I take the first as your definition of how you are using the term "clock rate"; it is not the only possible definition, but I have no problem using yours for this discussion.

You've left out a key piece of information here: is the front clock at rest, in frame F, at event e2? (By hypothesis the rear clock is at rest in frame F at event e1.)

That's not really relevant to the question of what is the ratio of clock rates, as measured by an observer in the rear of the rocket. But in the way I've set things up, the answer is "yes".

Same question here. I ask these, again, to make sure I understand the scenario you are talking about. I think the answer to both is "yes", but I would really like confirmation before going into details, since there's no point in my talking about a different scenario than you are talking about.

Whether the front clock is at rest at events e2 and e4 doesn't seem relevant to me. But if you work out the details for the constant proper acceleration, it turns out to be true, that in frame F, the front clock is at rest at event e2, and in frame F', the front clock is at rest at event e4.
 
  • #81
stevendaryl said:
That's not really relevant to the question of what is the ratio of clock rates, as measured by an observer in the rear of the rocket. But in the way I've set things up, the answer is "yes".

Whether the front clock is at rest at events e2 and e4 doesn't seem relevant to me. But if you work out the details for the constant proper acceleration, it turns out to be true, that in frame F, the front clock is at rest at event e2, and in frame F', the front clock is at rest at event e4.

Thanks for the confirmation. The reason it's relevant (other than giving me confirmation that I was correctly understanding your scenario) is the clock postulate, which I referred to before. Consider what you have here: you have two pairs of events, at each of which two objects are mutually at rest. By the clock postulate, then, their "instantaneous clock rates" should be the same, because their velocities, relative to any inertial frame, are the same, therefore their "time dilation factors", relative to any inertial frame, are the same. Yet between their respective events, one object (the front clock) experiences more elapsed time than the other (the rear clock).

In fact it's even weirder than that. Consider the entire worldlines of the two clocks; I'll write their equations in the "launch frame" as follows:

Rear clock: x^2 - t^2 = R^2

Front clock: x^2 - t^2 = (R + L)^2

Now draw any straight line through the origin, in the "launch frame", t = vx, where v >= 0. This is either a horizontal line (for v = 0) or a line sloping up and to the right at less than 45 degrees (for v > 0). Call the event where the line intersects the rear clock's worldline Rv, and the event where the line intersects the front clock's worldline Fv. Then all of the following are true:

(1) For any v, the line t = vx is a "line of simultaneity" in the instantaneous rest frame of the rear clock at Rv *and* of the front clock at Fv. Therefore, Rv and Fv are simultaneous as seen by both the front and the rear clocks.

(2) For any v, relative to the launch frame, the rear clock at Rv and the front clock at Fv are both moving at velocity v. Therefore, the front and rear clocks both see each other as at mutual rest at these events, and they both have the same "time dilation" factor at these events (because of the clock postulate).

(3) For any v, the proper time experienced by the front clock between F0 and Fv is greater, by the ratio (R+L)/R, than the proper time experienced by the rear clock between R0 and Rv.

So we have two clocks, which remain a constant distance apart at mutual rest, and have the same "time dilation factor" at any pair of corresponding events, and yet experience different proper times between corresponding events. I realize all this is true; I just point it out to explain why one has to be careful using the term "clock rate" without more explanation. Many people will think "time dilation factor", as in 1/sqrt(1 - v^2), when they see "clock rate" (after all, that's what I initially thought when I saw it), but that's not what you mean by the term. In particular, I think this may be one source of confusion in some of Austin0's posts.
 
Last edited:
  • #82
PeterDonis said:
Thanks for the confirmation. The reason it's relevant (other than giving me confirmation that I was correctly understanding your scenario) is the clock postulate, which I referred to before. Consider what you have here: you have two pairs of events, at each of which two objects are mutually at rest. By the clock postulate, then, their "instantaneous clock rates" should be the same, because their velocities, relative to any inertial frame, are the same, therefore their "time dilation factors", relative to any inertial frame, are the same. Yet between their respective events, one object (the front clock) experiences more elapsed time than the other (the rear clock).

For problems involving acceleration, time dilation is not the only consideration. Let's consider a variant of the old twin paradox. We have two twins that are the same age, but live on different planets, light-years apart. One twin on his 20th birthday hops into a rocket and accelerates rapidly to nearly the speed of light and gets to his other twin in just one year, according to the clock in his rocket. But the other twin has aged 20 years during the trip. How did that happen? From the point of view of the traveling twin, the trip only lasted a year. How could the other twin age 20 years?

Well, what you have to take into account is that simultaneity is relative. Let e1 be the traveling twin celebrated his 20th birthday. Let e2 be the event at which the distant twin celebrated his 20th birthday. Let F be the "launch" frame of the traveling twin, and let F' be the "traveling" frame. Events e1 and e2 are simultaneous in frame F, but not in frame F'; in frame F', e2 took place long, long before e1. So in jumping from frame F to frame F', the traveling twin changed his notion of what time "now" is on the distant planet, and so he changed his notion of how old the distant twin is.

So for an accelerated observer, the time on a distant clock changes both because that clock advances, and also because the observer's notion of what is "now" for the distant clock changes.
 
  • #83
stevendaryl said:
So for an accelerated observer, the time on a distant clock changes both because that clock advances, and also because the observer's notion of what is "now" for the distant clock changes.

Yes, the "simultaneity lines" t = vx that I described illustrate this: they change slope as v increases, meaning that the direction between the rear clock's "now" and the front clock's "now" changes. That means a given segment of the rear clock's worldline includes a set of simultaneity lines that sweep over a larger segment of the front clock's worldline. It's the hyperbolic equivalent of concentric circles, where the same angle sweeps out a longer arc on the circle with a larger radius.
 
  • #84
PeterDonis said:
I haven't been following this thread closely, and I can see a lot of formulas have been written down that I have not looked at in detail, ...

Just to summarise, the various formulas written down by Dalespam, stevendaryl and myself for the relative red shift of clock rates on board the accelerating rocket, as measured by observers on board the accelerating rocket are all equivalent, i.e.:

[tex]\frac{\Delta\tau_2}{\Delta\tau_1} = (1+g_1L/c^2) = \frac{R_2}{R_1} = \frac{g_1}{g_2}[/tex]

To the accelerated observers on board the rocket, the clocks remain at constant distance from each other, so from their point of view, none of the observed red shift is due to classical Doppler shift caused by relative velocities.
 
  • #85
yuiop said:
This is not what would be observed on board the rocket(s) because the time (t) here is the simultaneous coordinate time in the launch frame and the notion of what is simultaneous is different on board the rocket(s). This is the crux of the matter that I shall come back to.
After doing the calculations I am now sure that is what would be observed as coordinate velocity increases relative to any given MCIRF, as measured relative to the simultaneous coordinate time in that given MCIRF. As above, it is the notion of simultaneity that is important and this changes with reference frames and you have not been careful to specify one.
Only one. The launch frame.

yuiop said:
Nothing. Velocity time dilation still occurs, but the effect cancels out. Consider two signals emitted simultaneously from the front and back of a rocket at coordinate time t=0 as measured in a given MCIRF. To give this MCIRF a label I will call it the launch frame (LF), but there is nothing special about this MCIRF and I could do an identical analysis in any other MCIRF. When the signal from the front arrives at the back let us say the velocity in the LF is vb and when the signal from the back arrives at the front, the velocity in the LF is vf. It turns out that with Born rigid acceleration, vb = vf.

i am not sure if this actually tracks. If the signals are simultaneous in the emission MCIRF it appears unlikely the reception ,in a frame which would be many frames and spatial distance removed, would be simultaneous. I will have to work on this.

yuiop said:
This means that sqrt(1-(vb)^2) = sqrt(1-(vf)^2) so at the time of the reception of the signals the velocities and velocity based time dilation is identical at back and front and so there is no differential time dialtion between back and front due to velocity time dilation. All the apparent differential time dilation observed on board the rocket is due to classical Doppler shift according to the observer in the inertial LF.

even if your assumption is correct and the reception is simultaneous wrt the MCIRF how does this imply no velocity dilation?? by definition there is no motion relative to the MCIRF's
so any calculation based on the MCIRF couldn't reveal relative velocity between front and back.

When you say here the observer in the LF do you mean the initial launch frame or the current mCIRF ,,,,earlier you were referring to MCIrfs as LF
In any case Doppler shift is as you say ,apparent dilation, so not really relevant

yuiop said:
Well now we are back to the crux of the problem. I have been putting this off because while I feel I understand it intuitively in my head, putting it into words is not so easy :) The first fdifficulty is how to define a notion of simultaneity for the observers on board the rocket, when there own reference clocks appear to be running at different rates in different locations on board the rocket. If we ask the observers at the front and back of the rocket to send signals simultaneously in there own reference frame, how are they going to arrange that? One way to do this would be to agree a convention that defines "simultaneous" events at the front and back of the rocket as being events that are both simultaneous in a shared MCIRF. If they do this they will observe that the signals are received at the back and front "simultaneously" because the reception events will be simultaneous in a shared MCIRF, (but this shared MCIRF will not be the same shared MCIRF that the signals were emitted simultaneously in). For a practical example, let's say we an inertial rocket ir1 moving at 0.6c and another ir2 moving at 0.8c both relative to the LF. After launch we tell the observers at the front and back to send a signal at the moment they are at rest with ir1, then for a suitable length accelerating rocket, they will both receive signals when they are momentarily at rest with ir2. You might argue that I have cheated here, because I have simply defined, rather than derived a notion of simultaneous for the accelerating rocket observers

I think you misunderstood my question. I am aware of the problems implementing simultaneity in this circumstance , i mentioned a few earlier.
the question was why take an approach which had these problems and the inherent ambiguity of the result due to these problems.??

yuiop said:
Another approach is to speed up the rear clock (as mentioned in an earlier post) so that it appears to be running at the same rate as the front clock. Now we have an unequivocal method of defining simultaneous in the accelerating rocket reference frame and can synchronise clocks using the usual Einstein clock synchronisation convention. Now when we send signals from the front and back using the on board rocket reference clocks, the signals arrive simultaneously at the back and front respectively according to the rocket clocks and the elapsed time between sending and receiving is equal according to both the front and back accelerating rocket observers.

well I have to disagree here. Simply scaling the clocks does not make it an inertial frame.
It is still an accelerating system.
Even disregarding the acceleration/velocity differential, a synchronization which works for one velocity cannot work for other different velocities. Yeah?? How could it?

yuiop said:
If they consider themselves to be stationary in their own reference frame they would ascribe this differential clock rate to a gravitational field and this coincides with the proper acceleration they can feel and and measure. The observers in a given inertial reference frame outside the rocket would ascribe the differential clock rates observed by the rocket observers to classical Doppler shift.

yuiop said:
The snag is that the by calculating the relative time dilation by using the relative velocities at the front and back of the rocket one comes to the conclusion that the relative rates of clocks on board the rocket as measured by observers on board the rocket increases over time which is simply not true. The relative rates of clocks on board the rocket as measured by observers on board the rocket is constant over time.

I think you have misunderstood both my approach and point.

regarding measurement of relative clock rates at the front and back from the launch frame. LF accelerating system AF
Simultaneity is not an issue. measurement of clock rates of course requires some interval of time a single event doesn't work.

so in LF at (bxo,t0) (fx0 ,t0) we get

observations bT'0 and fT'0 of AF ..

at some later point at (bx1, t1), (fx1,t1)

we get observations bT'1 and fT'1 of AF

(bx) t1 - (bx)t0 = (bx)dt

(fx)t1 -(fx)t0 = (fx)dt

bT1-bT0 =dbT'

fT1 - fT0= dfT

then (fx)dt/[itex]\gamma[/itex] =dfT' and (bx)dt/[itex]\gamma[/itex]=dbT' or not

Would you agree that in this circumstance the simultaneity of the LF clocks at either measurement is not important because there is no direct comparison between the observations between them?
The comparison is between an observation of the back clock with a later observation of the back clock.Etc.

Of course it would be necessary to calculate the proper times for these events using the Rindler coordinates to make these comparisons.

Also the measurement points could be widely separated say 0.7c and 0.8c

More and more i suspect that the velocity dilation would be insignificant and might possibly agree with the Rindler predictions. I.e. would not increase with greater velocities. The acceleration magnitudes you used were totally unrealistic. The back of the rocket quickly passing the front and leaving it in the dust ;-) so I am still unsure.
thanks
 
Last edited:
  • #86
Austin0 said:
i am not sure if this actually tracks. If the signals are simultaneous in the emission MCIRF it appears unlikely the reception ,in a frame which would be many frames and spatial distance removed, would be simultaneous. I will have to work on this.
It does track. See the attached chart showing two rockets with Born rigid acceleration. Each time signals (black diagonal lines) are emitted simultaneously in one MCIRF, they are received simultaneously in a subsequent MCIRF. In the chart green curves represent equal proper time for the rocket clocks, red lines represent lines of equal velocity relative to the LF (or subsequent MCIRFs) and the blue lines represent the worldlines of the rockets in the LF. Note the constant nature of the redshift. Signals sent every 3 ticks from the rear rocket are received every 4 ticks by the leading rocket.
Austin0 said:
even if your assumption is correct and the reception is simultaneous wrt the MCIRF how does this imply no velocity dilation?? by definition there is no motion relative to the MCIRF's so any calculation based on the MCIRF couldn't reveal relative velocity between front and back.
You have the reasoning reversed. The MCIRFs reveal that there is no relative velocity in the reference frames of the accelerating rockets. You are right that simultaneously at given instant (other than t=0) in the LF, the velocities of the front and rear rockets are different, but this simultaneity does not apply to the accelerating reference frame. We can for example show that if there is no length contraction and the rockets are accelerating identically in the LF, that differential time dilation is still occurring in the rocket reference frame.
Austin0 said:
When you say here the observer in the LF do you mean the initial launch frame or the current mCIRF
Here I meant LF, as in pick one MCIRF and stick with it, rather than keep switching to subsequent MCIRFs.
Austin0 said:
,,,,earlier you were referring to MCIrfs as LF
I just meant you could pick any arbitrary MCIRF as a LF. There is nothing particularly special about the LF. The rockets are still accelerating even in the LF.
Austin0 said:
In any case Doppler shift is as you say ,apparent dilation, so not really relevant
This is the bizarre aspect. The inertial observer attributes the redshift to classical Doppler shift due to velocity differential between emission and reception and yet the time dilation observed by the accelerating observers is real (as in physical) and an observer in the rear rocket really ages slower than an observer in the front rocket.
Austin0 said:
the question was why take an approach which had these problems and the inherent ambiguity of the result due to these problems.??
.. because nature does not give us much choice and there is no natural way to have synchronised clocks and static coordinate system in an accelerating reference frame or in a gravitational field.
Austin0 said:
well I have to disagree here. Simply scaling the clocks does not make it an inertial frame.
It is still an accelerating system.
Yes, it is still an accelerating system and I never claimed to make it an inertial reference frame. I only claimed it gave us a way to have a sensible coordinate system and a way to synchronise clocks that gives a static reference system with coordinate axes that are not changing over time. Can you suggest another way to synchronise clocks that are running at different rates?
Austin0 said:
Even disregarding the acceleration/velocity differential, a synchronization which works for one velocity cannot work for other different velocities. Yeah?? How could it?
It does work for other velocities. Have another look at the posted chart. The rear rocket sends signals every 3 ticks and the front rocket receives those signals every 4 ticks, consistently even as the relative rocket velocities constantly change over time. If we speed up the rear clock by a factor of 4/3 then the front observer will see the rear clock ticking at the same rate as his own clock for all time.
Austin0 said:
Also the measurement points could be widely separated say 0.7c and 0.8c

More and more i suspect that the velocity dilation would be insignificant and might possibly agree with the Rindler predictions. I.e. would not increase with greater velocities. The acceleration magnitudes you used were totally unrealistic. The back of the rocket quickly passing the front and leaving it in the dust ;-) so I am still unsure.
thanks
Again, if you look at the attached chart you see that the front rocket sends a signal when the rocket velocities in the LF are approximately 0.69c and the rear rocket receives that signal when the rocket velocities are approximately 0.81c in the LF and there are no problems with the rear rocket overtaking the front rocket. (Another curious aspect is that a light signal sent from left of the origin can never catch up with the accelerating rockets, even though they never attain light speed. That should bake your noodle! :devil: ).

P.S. I think Peter has a pretty good handle on it all in post #81.
 

Attachments

  • AccelDoppler.gif
    AccelDoppler.gif
    23.8 KB · Views: 459
Last edited:
  • #87
yuiop said:
[..] This is the bizarre aspect. The inertial observer attributes the redshift to classical Doppler shift due to velocity differential between emission and reception and yet [..] an observer in the rear rocket really ages slower than an observer in the front rocket.
That looks bizarre because it's wrong. Indeed the redshift of accelerating rockets is almost purely (semi)classical Doppler shift, insofar as there is no or negligible difference in acceleration. I see no reason for the claim that in reality it's not so, as I also stressed in post #65:
harrylin said:
- The equivalence principle has that the observable effect will be the same. Einstein calculated (predicted) what the observable effect will be due to gravitation, basing himself on the observable Doppler effect due to acceleration.
Thus the clock at the bottom of the ship will only *appear* to slow down by the gravitational time dilation factor *if* you assume that the ship is not accelerating but at rest in a gravitational field. If instead you assume, as you do, that there is negligible gravitational field, then the clock at the rear will really *not* slow down (at least, by far not by that amount) compared to the one at the front.
It depends on your choice of inertial reference system if you deem that the clock in the rear ages slower or not; according to the launch frame's POV they age equally.
 
Last edited:
  • #88
harrylin said:
That looks bizarre because it's wrong. Indeed the redshift of accelerating rockets is almost purely (semi)classical Doppler shift, insofar as there is no or negligible difference in acceleration. I see no reason for the claim that in reality it's not so, as I also stressed in post #65:
Are you talking about the case with no length contraction or the case with length contraction as used in in Rindler coordinates or Born rigid acceleration? In the latter case there is most definitely significant difference in proper acceleration as measured on board the rockets and a significant difference in coordinate acceleration as measured simultaneously in the launch frame
harrylin said:
It depends on your choice of inertial reference system if you deem that the clock in the rear ages slower or not; according to the launch frame's POV they age equally.
They only age equally from the launch frame's POV if there is no length contraction. Even then, the rear rocket observers will see blue shift of clocks at the front of the rocket and any experiment they carry out will convince them that the rear clocks are tangibly running slower than the front clocks. In this thread we are mainly discussing the equivalence between measurements in an artificially accelerated system and a gravitational system, so we are more interested in what the accelerated observers measure. Also, the case where there is length contraction such that the accelerated observers consider themselves to be at constant distance from each other, is more relevant to a typical gravitational field such as that of the Earth. When we stand on top of a tower and look towards the base, we generally consider the height of the tower to remain constant.

P.S. Some reservations about the none length contracting case have occurred to me. I will try to analyse that in detail later.
 
Last edited:
  • #89
yuiop said:
Are you talking about the case with no length contraction or the case with length contraction as used in in Rindler coordinates or Born rigid acceleration? [..]
I thought that you were talking about the case with no length contraction as seen from the launch pad frame. Else a little correction is needed, as I also hinted at in my post #65 which I also cited again. I thought (and still think) that you were not talking about that small effect of length contraction when you made your claim about "really slower aging", as that redshift is very small compared to "the redshift" that you discussed. If I misunderstood you, please clarify. :smile:
[...] any experiment they carry out will convince them that the rear clocks are tangibly running slower than the front clocks.[..]
Only if, as I pointed out, he is fooling himself into thinking that he his not accelerating. However, that would not be reasonable for someone in a rocket with firing rocket engines - as you also seemed to realize in your answer in post #73. For some reason that escapes me, you replaced "fooled"(=not real) by "real" (=true) between that post and post #86. Someone's instrument reading is not necessarily identical to "what really happens", nor does a smart rocket pilot accept everything at face value.
 
Last edited:
  • #90
harrylin said:
I thought that you were talking about the case with no length contraction as seen from the launch pad frame. Else a little correction is needed, as I also hinted at in my post #65 which I also cited again. I thought (and still think) that you were not talking about that small effect of length contraction when you made your claim about "really slower aging", as that redshift is very small compared to "the redshift" that you discussed. If I misunderstood you, please clarify. :smile:

I'm not sure exactly what you are claiming. The differential aging of someone in the front and rear of a rocket is real. We can make it operational as follows:
  1. Take a pair of clocks to the rear of the rocket.
  2. Set them to the same time, t=0.
  3. Move one of the clocks to the front of the rocket.
  4. Wait a year.
  5. Move it back to the rear.
  6. Compare the two clocks.

The prediction is that if we allow length contraction (Born rigid acceleration) then the moving clock will be ahead of the clock that was always in the rear by a factor of 1+gL/c2. So it's not simply some kind of illusion.
 
  • #91
harrylin said:
I thought that you were talking about the case with no length contraction as seen from the launch pad frame. Else a little correction is needed, as I also hinted at in my post #65 which I also cited again. I thought (and still think) that you were not talking about that small effect of length contraction when you made your claim about "really slower aging", as that redshift is very small compared to "the redshift" that you discussed. If I misunderstood you, please clarify. :smile:
Generally when I talk about accelerating rockets in this thread I am talking about the the length contraction version and when I am talking about the more unusual and perhaps less useful none length contracting version I usually make it clear that I am talking about that version. In my last post I mentioned that I intend to analyse the none length contraction version more closely as that might be interesting.
harrylin said:
Only if, as I pointed out, he is fooling himself into thinking that he his not accelerating. However, that would not be reasonable for someone in a rocket with firing rocket engines - as you also seemed to realize in your answer in post #73. For some reason that escapes me, you replaced "fooled"(=not real) by "real" (=true) between that post and post #86. Someone's instrument reading is not necessarily identical to "what really happens", nor does a smart rocket pilot accept everything at face value.
When Einstein introduced the equivalence idea he described comparing measurements in a closed accelerating box so that the observers inside would be unaware of whether they were stationary in a gravitational field or accelerating artificially in flat space. Without the luxury of being able to look out the window he would no be aware of his rocket engines fireing away. In both cases he would measure proper acceleration and redshift of signals from below him and in a small enough enclosure whereby tidal effects are negligable, he would be "fooled", in the sense that he would be uncertain as to whether he was being artificially accelerated in flat space or stationary in a gravity field. In both the artificially accelerated case and when stationary in a gravity field, clocks lower down really and unambiguously run slower than clocks higher up. No one is being fooled about whether the clocks run at different rates or not.
 
Last edited:
  • #92
yuiop said:
Generally when I talk about accelerating rockets in this thread I am talking about the the length contraction version and when I am talking about the more unusual and perhaps less useful none length contracting version I usually make it clear that I am talking about that version.
When Einstein introduced the equivalence idea he described comparing measurements in a closed accelerating box so that the observers inside would be unaware of whether they were stationary in a gravitational field or accelerating artificially in flat space. Without the luxury of being able to look out the window he would no be aware of his rocket engines fireing away. In both cases he would measure proper acceleration and redshift of signals from below him and in a small enough enclosure whereby tidal effects are negligable, he would be "fooled", in the sense that he would be uncertain as to whether he was being artificially accelerated in flat space or stationary in a gravity field. In both the artificially accelerated case and when stationary in a gravity field, clocks lower down really and unambiguously run slower than clocks higher up. No one is being fooled about whether the clocks run at different rates or not.
And to what do you attribute the different rates if differential velocity is ruled out??
 
  • #93
Austin0 said:
And to what do you attribute the different rates if differential velocity is ruled out??
I guess the inertial observer would attribute part of the differential rates to differential velocity, but the Rindler observers on board the rockets would not because as far as they are concerned the rockets are stationary with respect to each other and they would have to attribute the differential clocks rates to a real or pseudo force field.
 
  • #94
stevendaryl said:
I'm not sure exactly what you are claiming. The differential aging of someone in the front and rear of a rocket is real. We can make it operational as follows:
  1. Take a pair of clocks to the rear of the rocket.
  2. Set them to the same time, t=0.
  3. Move one of the clocks to the front of the rocket.
  4. Wait a year.
  5. Move it back to the rear.
  6. Compare the two clocks.
The prediction is that if we allow length contraction (Born rigid acceleration) then the moving clock will be ahead of the clock that was always in the rear by a factor of 1+gL/c2. So it's not simply some kind of illusion.
Your operation is quite different from the one I commented on, and I have not analysed yours. I thought that Yuop was discussing clocks in two rockets, and thus I assumed a similar situation as Bell's spaceships.
yuiop said:
[..] he would be uncertain as to whether he was being artificially accelerated in flat space or stationary in a gravity field. In both the artificially accelerated case and when stationary in a gravity field, clocks lower down really and unambiguously run slower than clocks higher up. No one is being fooled about whether the clocks run at different rates or not.
In a case of two rockets such as presented by Bell, according to the launch frame observation the two clocks will age identically, and that observation is as valid as any other one; and note that the Doppler redshift will be nearly the same as in a case with length contraction. If instead we consider a single rocket as viewed from the launch frame then there will be a small effect due to length contraction (I did not calculate it or analyse from all perspectives, but at first sight it gives a slight slowdown of the rear clock according to all observers). You did not reply my question to you if indeed you were talking about the (much bigger?) effect of Doppler redshift.
 
Last edited:
  • #95
harrylin said:
Your operation is quite different from the one I commented on, and I have not analysed yours (but I did qualitatively analyse a similar one, see next). I thought that Yuop was discussing clocks in two rockets, and thus I assumed a similar situation as Bell's spaceships.

In a case of two rockets such as presented by Bell, according to the launch frame observation the two clocks will age identically, and that observation is as valid as any other one. If instead we consider a single rocket as viewed from the launch frame then there will be a very small effect due to length contraction (I did not calculate it or analyse from all perspectives, but at first sight it gives a slight slowdown of the rear clock according to all observers). You did not reply my question to you if indeed you were talking about the much bigger effect of "gravitational" (Doppler) redshift.

I think we are all talking now about the length contracted case. either as a single rocket or two rockets with the expected contraction effected through differential acceleration.

So there are three questions;

1) How much dilation would be effected purely through length contraction ?[which i think would have to be calculated from the launch frame , not momentarily comoving frames]
]
2) Would this dilation factor increase over time with greater velocities?.

3)how would this figure compare with the expected relative dilation in the accelerating system as calculated using the Rindler coordinates?

1+gL/c2. yes i think they are talking about this factor as being actual dilation , not apparent Doppler dilation
 
  • #96
Austin0 said:
I think we are all talking now about the length contracted case. either as a single rocket or two rockets with the expected contraction effected through differential acceleration. [..] 1) How much dilation would be effected purely through length contraction ?[which i think would have to be calculated from the launch frame , not momentarily comoving frames] [..]
I was still editing my answer when you answered, as just after answering I got the impression that although I wasn't commenting on the calculations, someone (perhaps me) may have made an error related to the numbers. But if so, I haven't yet figured out where...

In any case, answers to your questions will also clarify that point for me! (now I have now no time to look at it myself).
 
  • #97
harrylin said:
Your operation is quite different from the one I commented on, and I have not analysed yours. I thought that Yuop was discussing clocks in two rockets, and thus I assumed a similar situation as Bell's spaceships.

Well, the difference between the two rocket case and the one-rocket case is length contraction. In the two-rocket case (with identical accelerations), the clocks will always show the same time in the "launch" frame, but the front clock will run ahead of the rear clock in the instantaneous comoving frame of the rear clock.

In a case of two rockets such as presented by Bell, according to the launch frame observation the two clocks will age identically, and that observation is as valid as any other one;

Well, sort of. I thought you were saying that the differential aging was a kind of illusion, which I interpreted as saying that they were really the same age. The relative age of distant twins (or clocks--I forget which we're talking about) is a frame-dependent quantity, but I wouldn't call that an illusion.

and note that the Doppler redshift will be nearly the same as in a case with length contraction. If instead we consider a single rocket as viewed from the launch frame then there will be a small effect due to length contraction

It's not a small effect, when you consider the case of the rocket accelerating for long periods of time. As I have pointed out in a different post, the time difference between the times on the front and rear clocks can be broken down into two contributions:

Let e1 be the event at which the rear clock shows time T1. Let e2 be the event at the front clock that is simultaneous with e1, according to the "launch" frame. Let T2 be the time on the front clock at event e2. Let e3 be the event at the front clock that is simultaneous with e1 in the comoving frame of the rocket. Let T3 be the time on the front clock at event e3.

Let δT1 = T2 - T1.
Let δT2 = T3 - T2.

δT1 is purely due to length contraction; it's equal to 0 if there is no length contraction (the two-rocket case).

δT2 is an additional contribution due to relativity of simultaneity; what's simultaneous in the launch frame is not simultaneous in the comoving frame.

δT1 starts off zero and gradually gets bigger and bigger, growing without bound, if the two clocks continue accelerating.

δT2 starts off nonzero, and approaches a maximum value.

The total discrepancy between the two clocks, as viewed by the comoving frame of the rocket, is the sum of the two δT = δT1 + δT2. That sum grows at a constant rate of gL/c2; that is, δT/T1 = gL/c2 at all times.

The two effects, length contraction and relativity of simultaneity, are both important in explaining the discrepancy between the two clocks. Relativity of simultaneity is the dominant effect soon after launch, and length contraction is the dominant effect long after launch.
 
  • #98
Austin0 said:
I think we are all talking now about the length contracted case. either as a single rocket or two rockets with the expected contraction effected through differential acceleration.

So there are three questions;

1) How much dilation would be effected purely through length contraction ?[which i think would have to be calculated from the launch frame , not momentarily comoving frames]
]
2) Would this dilation factor increase over time with greater velocities?.

I think those questions have already been answered. The effect due to length contraction starts off zero, and increases without bound. Long after launch, the ratio of the time on the front clock to the time on the rear clock approaches the value 1+gL/c2, as measured in the launch frame.

3)how would this figure compare with the expected relative dilation in the accelerating system as calculated using the Rindler coordinates?

1+gL/c2. yes i think they are talking about this factor as being actual dilation , not apparent Doppler dilation

Well, "actual" versus "apparent" is a fuzzy distinction. The time difference is real, in the operational sense that I gave: If you synchronize two clocks in the rear, take one clock to the front and let it sit for a year, and then bring it back to the rear, the clock that was in the front will show more elapsed time. And the difference will be exactly what the Doppler shift showed.
 
  • #99
stevendaryl said:
[..] I thought you were saying that the differential aging was a kind of illusion, which I interpreted as saying that they were really the same age. The relative age of distant twins (or clocks--I forget which we're talking about) is a frame-dependent quantity, but I wouldn't call that an illusion.
Instead I was saying that the pseudo gravitational field is a kind of illusion, and I simply tried to clarify in post #87 that as the inertial observer attributes the redshift at low relative velocity to classical Doppler shift, an observer in the rear rocket cannot be said to really age slower by this red shift factor than an observer in the front rocket - and thus there is nothing "bizarre" going on here.
The two effects, length contraction and relativity of simultaneity, are both important in explaining the discrepancy between the two clocks. Relativity of simultaneity is the dominant effect soon after launch, and length contraction is the dominant effect long after launch.
Thanks for the analysis with which I agree (only what you call "relativity of simultaneity", I call Doppler shift). It's interesting to see that at very high speeds the effect is mainly attributed to length contraction, indeed I had not realized that.
 
Last edited:
  • #100
harrylin said:
Instead I was saying that the pseudo gravitational field is a kind of illusion, and I simply tried to clarify in post #87 that as the inertial observer attributes the redshift at low relative velocity to classical Doppler shift, an observer in the rear rocket cannot be said to really age slower by this red shift factor than an observer in the front rocket - and thus there is nothing "bizarre" going on here.
If we have twins at the front of the rocket (initially the same age) and one free falls to the rear of the rocket and some time later the other free falls to the rear of the rocket, the twin that spent the most time at the rear of the rocket will have physically aged less than the twin that spent the most time at the front of the rocket. When we compare twins side by side and observe differential ageing, that is as real as it gets, as far as time dilation is concerned.
 
  • #101
yuiop said:
[..] When we compare twins side by side and observe differential ageing, that is as real as it gets, as far as time dilation is concerned.
Surely we all agree on that; it's different from the case that you discussed in which their ages are not compared side by side. Why did you find that case bizarre?
 
<h2>1. What is the equivalence principle?</h2><p>The equivalence principle is a fundamental concept in physics that states that the effects of gravity are indistinguishable from the effects of acceleration. This means that an observer in a uniform gravitational field cannot tell the difference between being at rest in that field or accelerating through empty space.</p><h2>2. Who first proposed the equivalence principle?</h2><p>The equivalence principle was first proposed by Albert Einstein in his theory of general relativity in 1915. However, the concept had been discussed by other scientists, including Galileo and Newton, in different forms prior to Einstein's formulation.</p><h2>3. What is the significance of the equivalence principle?</h2><p>The equivalence principle is significant because it forms the basis of general relativity, which is one of the most successful and widely accepted theories in physics. It also has important implications for our understanding of gravity and the behavior of objects in the universe.</p><h2>4. How is the equivalence principle tested?</h2><p>The equivalence principle has been tested in many ways, including experiments using pendulums, free-falling objects, and precision measurements of gravitational fields. One famous experiment is the Eötvös experiment, which compared the acceleration of different materials in a gravitational field.</p><h2>5. Are there any exceptions to the equivalence principle?</h2><p>While the equivalence principle holds true in most situations, there are some cases where it does not apply. For example, at very small scales, such as in quantum mechanics, the effects of gravity and acceleration can be distinguished. Additionally, the equivalence principle does not hold in the presence of strong tidal forces, such as near a black hole.</p>

1. What is the equivalence principle?

The equivalence principle is a fundamental concept in physics that states that the effects of gravity are indistinguishable from the effects of acceleration. This means that an observer in a uniform gravitational field cannot tell the difference between being at rest in that field or accelerating through empty space.

2. Who first proposed the equivalence principle?

The equivalence principle was first proposed by Albert Einstein in his theory of general relativity in 1915. However, the concept had been discussed by other scientists, including Galileo and Newton, in different forms prior to Einstein's formulation.

3. What is the significance of the equivalence principle?

The equivalence principle is significant because it forms the basis of general relativity, which is one of the most successful and widely accepted theories in physics. It also has important implications for our understanding of gravity and the behavior of objects in the universe.

4. How is the equivalence principle tested?

The equivalence principle has been tested in many ways, including experiments using pendulums, free-falling objects, and precision measurements of gravitational fields. One famous experiment is the Eötvös experiment, which compared the acceleration of different materials in a gravitational field.

5. Are there any exceptions to the equivalence principle?

While the equivalence principle holds true in most situations, there are some cases where it does not apply. For example, at very small scales, such as in quantum mechanics, the effects of gravity and acceleration can be distinguished. Additionally, the equivalence principle does not hold in the presence of strong tidal forces, such as near a black hole.

Similar threads

  • Special and General Relativity
Replies
9
Views
879
  • Special and General Relativity
Replies
8
Views
867
  • Special and General Relativity
4
Replies
115
Views
5K
  • Special and General Relativity
2
Replies
44
Views
4K
  • Special and General Relativity
2
Replies
36
Views
2K
  • Special and General Relativity
Replies
11
Views
938
Replies
2
Views
662
  • Special and General Relativity
Replies
32
Views
3K
  • Special and General Relativity
Replies
7
Views
963
  • Special and General Relativity
Replies
8
Views
864
Back
Top