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name123 said:In the example do the satellites' have a nonzero proper acceleration?
No, they are in free fall orbits. But spacetime is curved because of the presence of the gravitating mass.
name123 said:In the example do the satellites' have a nonzero proper acceleration?
A stationary perspective is easy. That is completely different from an inertial frame. (I am not sure why you use the word imaginary here)name123 said:I thought that it would at least be possible that at least one imaginary perspective was considered to be stationary given the equations.
In relativity “perspective” usually means reference frame. You haven’t examined anything from any perspective because you have not defined any reference frame. This is why you need to learn some background information first.name123 said:I was just examining it from the satellites perspective.
The conceptual error is precisely avoiding the maths that are required to answer the question. If you had the mathematical background then you would understandname123 said:so perhaps instead just point out the conceptual error (no maths required).
Dale said:The conceptual error is precisely avoiding the maths that are required to answer the question. If you had the mathematical background then you would understand
1) why I am going on about reference frames
2) why @PeterDonis states that frames are not physical
3) why @Ibix is talking about finding and timelines
Would you like to start learning the background necessary to understand this material?
Certainly, here are the lecture notes I mentioned above:name123 said:Please enlighten the forum in relation to the scenario provided...
Dale said:Certainly, here are the lecture notes I mentioned above:
https://arxiv.org/abs/gr-qc/9712019
Here is a briefer introduction also by Sean Carroll:
https://preposterousuniverse.com/wp-content/uploads/2015/08/grtinypdf.pdf
And here is the first lecture in a video course by Leonard Susskind:
Dale said:I don't know if there is such a system.
Specifically, you should be comfortable with the material in the first two chapters in the Lecture notes. The third chapter would be optional. If that is too difficult then start with the brief introduction and the video lectures.name123 said:Could you possibly be more specific
Most of the disagreements are disagreements about how to rigorously interpret what you are saying, not about the underlying theory.name123 said:it seems that even your mentors have disagreed
It is still not obvious to me (you still have not specified the reference frame), and as I told you this is a difficult problem that I am not willing to work through. It is difficult, but I see minimal value to it. Presumably you feel it is a valuable question, so then you are the one that has the motivation to dig through the math to get the answer.name123 said:Presumably you knew the information in the links beforehand, and if it wasn't obvious to you but you have since worked it out, then perhaps share.
name123 said:even your mentors have disagreed
name123 said:whether there is a coordinate system in which the satellites from the A and B series would match clockwise when they passed
name123 said:Please enlighten the forum in relation to the scenario provided...
name123 said:So how does the visualisation you provided explain the same time logged for the spaceship flashes, between the satellite to the left and right of the satellite passing the passing ship (of whose perspective we are imagining) and the satellites to the left and right of the opposite satellite (from the one passing the ship)? Presumably those distances from north/south flashing spaceships are not the same. Nor their next positions.
The basic conceptual problem is that "the satellite's point of view" is not a precise definition of anything. You can get away with such imprecision in flat spacetime for non-accelerating objects because pretty much any reasonable construal of "point of view" turns out to mean standard issue Einstein frames. Not so in the general case.name123 said:I was just examining it from the satellites perspective. But if I have made a mistake then please point it out. I would be happy to see the perspective mathematically from the satellite's point of view, but given your request for money presumably you aren't going to, so perhaps instead just point out the conceptual error (no maths required).
I agree with everything that Ibix says in this post. However, I would like to suggest a simplification: suppose that we treat the satellite orbits as a classical central force problem instead of using gravity to keep them in their orbits... Now we can avoid the complexities of curved spacetime and work the problem in a single global inertial frame (the one in which Earth and spaceships are at rest is of course a sensible one) using the simpler methods of SR with a natural way of correcting for light travel time.Ibix said:The basic conceptual problem is that "the satellite's point of view" is not a precise definition of anything...
Indeed. So we have two co-axial counter-rotating merry go rounds with clocks on their rims. I think the only real difference this makes to my answer is that the maths of working out what each clock actually sees from a counter-rotating clock is merely annoying, not actively difficult.Nugatory said:This simpler setup still captures what I think is the essence of @name123's problem: How can it be that all the satellites log the same arrival time for the flashes, and their clocks match when they meet every half-orbit, even though the clocks on the satellites are mutually time-dilated so that the satellite observers will always find all the other satellite clocks to running slow for the entire orbit?
I agree, that is a much better problem. Of course, even in flat spacetime there is not one unique definition of the reference frame for a non-inertial observer. So the OP will still need to specify what reference frame he wants to use to indicate the satellite's reference frame as a transformation from some inertial frame.Nugatory said:This simpler setup still captures what I think is the essence of @name123's problem
Janus said:well as with any scenario where you have relative motion, you do have to take the relativity of simultaneity in account.
To demonstrate we will just consider linear motion.
Below is a rod from which light flashes initiate at the ends To the left is how events occur according to the rod itself. The flashes start at the same time and the expanding light meets at the center of the rod.
On the right are the same events according to someone for which the rod is moving at 0.5c to the right.
The flash from the left end of the rod starts first, and the light expands outward at c while the rod continues to move to the right.
After the rod has moved some distance, the second flash leaves the right end, and expands out at c. Both flashes continue to expand as the rod continues to move to the right until they meet, again at the middle of the rod.
View attachment 228688
The fact that the light meets at the center of the rod is an invariant fact for both frame. Whether or not each flash started at the same time is not.
So in your scenario, the fact that flashes from the spacecraft arrive at all the satellites simultaneously in one frame does not mean that they arrive simultaneously in all frames. In the same way, the fact that two satellites are always in sync when they pass each other is an invariant fact doesn't mean that they remain in sync at all points of their orbits in all frames.
name123 said:The problem I would have with it is that if their clocks are going slower how do they show the same time per orbit. Could you perhaps explain it in terms of mathematical example, or explain conceptually the error I made? I imagine it as rotating a cardboard cutout around an axis, (different spoke lengths for different satellites) but having a problem of the clocks on some satellites (rather than their velocities) going slower than others but measuring the same time per orbit.
name123 said:Just to be clear what I mean is that if in your chosen frame of reference each satellite receives each light flash from the spaceships at the same time, and at that time (according to your calculations for that frame of reference) some of their clocks were going at different rates to other ones, then how comes when they come to log the time they detected the flash of light they all report the same time on their clocks.
The problem with your description of post 43 is that you were describing a lot of features and details that you assumed that "the satellite's frame" would have without actually writing down what you mean by "the satellite's frame" and showing that it actually has those features. There is simply no way to avoid it. The satellites are non-inertial, so there is no default frame to use that we consider to be their frame. You actually have to specify it explicitly, e.g. as a transform between the ship's frame which is inertial.name123 said:I had already explained in post #43 how I was visualising it. And there it was clear that I was not thinking that from a satellite's perspective all the satellites were receiving the signal at the same time (because their distance to the shapeship flashing would be different).
Janus said:Assuming you had a spaceship( the red arrow in the following image) skimming the orbit of a ring of satellites such that it momentarily matches the velocity of the satellite it is passing, then,...
The short lines are not a problem. The bends between the short lines are. They have to be accounted for. Each bend changes the simultaneity convention used between the one tangent inertial frame and the next.name123 said:series of short lines
jbriggs444 said:The short lines are not a problem. The bends between the short lines are. They have to be accounted for. Each bend changes the simultaneity convention used between the one tangent inertial frame and the next.
Yes, I think it is wrong. You cannot make a valid non-inertial frame by stitching together a bunch of inertial frames. When we say "the satellite's perspective" in relativity then we are talking about a reference frame where the satellites are at rest. Since they are non-inertial then there is no standard reference frame and it must be explicitly defined. A sequence of inertial frames does not represent the satellite's frame.name123 said:If you think both my and Janus's consideration that the orbits of the other satellites would appear elliptical is wrong, then please say so.
Dale said:Yes, I think it is wrong. You cannot make a valid non-inertial frame by stitching together a bunch of inertial frames. When we say "the satellite's perspective" in relativity then we are talking about a reference frame where the satellites are at rest. Since they are non-inertial then there is no standard reference frame and it must be explicitly defined. A sequence of inertial frames does not represent the satellite's frame.
Only if you define the transformation that way! You can define it largely arbitrarily, so it is up to you to include that feature if you see it as an important feature to include. This is something that is up to you to decide, and you do that by specifying the satellite's reference frame mathematically.name123 said:Ok, well however it would look for satellites of its own series, do you accept that it would look that way the whole way around given the symmetry?
Dale said:Only if you define the transformation that way! You can define it largely arbitrarily, so it is up to you to include that feature if you see it as an important feature to include. This is something that is up to you to decide, and you do that by specifying the satellite's reference frame mathematically.
You want to know what a satellite's clock shows at the same time as another satellite's clock reads 00.01, 00.02, 00.03 etc.name123 said:Ok, well however it would look for satellites of its own series, do you accept that it would look that way the whole way around given the symmetry?
name123 said:I thought it was obvious in post #43 I was considering that the satellite's perspective could be approximated by imagining a series of short lines where it is traveling at the velocity it is in the direction of it's tangent.
Yes, you have the freedom to define the transformation as something like:name123 said:Perhaps you could give an example of how it is arbitrary?
Again, this is not what happens or is observed. If a satellite is watching another satellite's clock (or via radio), when they are moving apart each will observe the other's clock to be running slower and when they are approaching each will observe the other's clock to be running faster.name123 said:I What I am having trouble with is the reconciliation of the clocks being considered as going slower on the other satellite the whole orbit...
Let us focus on what Stella and Terence actually see with their own eyes. (Just to emphasize that we're talking about direct observation here, I'll put the verb "see" and its brothers in the HTML strong font throughout this section.) To make things interesting, we'll equip them with unbelievably powerful telescopes, so each twin can watch the other's clock throughout the trip. If each twin saw the other clock run slow throughout the trip, then we would have a contradiction. But this is not what they see.
Just in case it's too hard to read the clock hands through the telescope, we'll add a flash unit to each clock, set to flash once a second. You might guess at first that Terence sees Stella's clock flashing once every 7 seconds (with the time dilation factor we've chosen) and vice versa. Not so! On the Outbound Leg, Terence sees a flash rate of approximately one flash per 14 seconds; on the Inbound Leg, he seesher clock going at about 14 flashes per second. That is, he sees it running fast! Stella sees the same behavior in Terence's clock.
Where "observe" refers to the frame invariant Doppler shift rather than some coordinate-dependent quantity.russ_watters said:Again, this is not what happens or is observed. If a satellite is watching another satellite's clock (or via radio), when they are moving apart each will observe the other's clock to be running slower and when they are approaching each will observe the other's clock to be running faster.
Indeed. If you want to know what a video camera mounted on one satellite and tracking another will actually record, @name123, then that's possible in principle. Even with Nugatory's simplified scenario it would involve numerical approximation, but it's possible. It's just that you can't work backwards to subtract out the Doppler effect without first picking a definition of "at the same time".Dale said:Where "observe" refers to the frame invariant Doppler shift rather than some coordinate-dependent quantity.
Ibix said:You want to know what a satellite's clock shows at the same time as another satellite's clock reads 00.01, 00.02, 00.03 etc.
Can you tell us what step in that chain of reasoning is escaping you?
- In relativity there is no general meaning to "at the same time".
- For inertial bodies in flat spacetime there is a sensible default guess as to what "at the same time" means (Einstein frames).
- This scenario is either not in flat spacetime (your formulation) or the satellites are not inertial (Nugatory's formulation).
- Thus there is no default sensible meaning to "at the same time".
- The only attempt you've made to define "at the same time" (chaining together small inertial frames) does not produce a consistent meaning (see post #69).
- You are free to define "at the same time" in many different ways. Pretty much the only constraints are that the other satellite's clock must always be advancing and we must not assign two times to the same event. The rate depends on your definition.
- Since you don't have a definition of "at the same time" forced on you or pre-selected by some mechanism then the question is pointless. The answer is "whatever you define it to be".
name123 said:Just to be clear what I meant, is that at no matter what part of the orbit the satellite is, its observational relationship to the other satellites in its series does not change. So that if there were no defining features on the "sphere" and no other things in the universe other than those being considered, you could not tell from photographs which part of the orbit the satellite was in. If you were already clear on that, then I am not sure what is arbitrary about it. Perhaps you could give an example of how it is arbitrary?
Dale said:Yes, you have the freedom to define the transformation as something like:
##t=\gamma T##
##r=R##
##\phi=\Phi+\omega T##
##z=Z##
or
##t=\gamma T##
## x= X \cos(\Phi+\omega T) + \gamma Y \sin(\Phi+\omega T) ##
## y= Y\cos(\Phi+\omega T) - \gamma X \sin(\Phi+\omega T) ##
##z=Z##
or
...
It is up to you.