A very simple question about general relativity

In summary, two colony ships launched from Earth 50,000 years ago and reverted to barbarism before regrowing a new technological society. They forgot their origins and purpose, but later discovered they were only a light-year away from each other and decided to join forces. However, one ship's propulsion system was broken, so the other ship accelerated at an incredibly high speed to dock with it. This resulted in time dilation, where one ship aged only a few hours while the other aged an entire year. A third party, Planet C, witnessed this and noted that both ships experienced time dilation due to the relativity of simultaneity and length contraction. When the ships finally met,
  • #36
Dropout said:
What people are telling me is the special relativity party line I've heard 100 times before. Do people in the ships only communicate with 1 flash of light? I think not, I think they would talk to each other. I am simply asking what Ship A and Ship B said to each other, and what planet C heard they say to each other. Its actually a very simple scenario, exactly like the twin paradox with a 3rd frame of reference thrown in. Is that's what's throwing you all off, a 3rd frame of reference?

The twin paradox works perfectly A-ok when dealing with 2 frames of reference, but can the relativity withstand a 3rd frame of reference? This isn't a complex scenario here, its pretty simple.

The twin paradox can easily withstand a third frame of reference.

Your question, however, remains ill-posed. What sort of conversations are you imagining that people have when it takes a year to get a reply to one's message?

As physicists, it's really not our job to write dialog for characters. If you can re-think your question in more physical grounds, we can probably provide an answer.

For instance, it's possible for us to imagine that each spaceship is sending regular pulses at 1 second intervals. (or 1 minute, or 1 hour, or whatever). And that all spacehsips each announce via a broadcast when some specific event is occurring - for instance, the spaceship that accelerates can announce "I am starting to accelerate".

The stationary spaceship cannot announce when the accelerating spaceship starts to accelerate, but it can announce when it actually sees the event hapen, so it can say "I see you start to move".

Both spaceships can announce, together "We're docked".

It's reasonably straightforwards, knowing the velocity, and the doppler shift formula

time ratio = [tex]\sqrt{\frac{c-v}{c+v}} [/tex] to find out how many pulses each observer receives.

So we can ask "How many pulses does the stationary spaceship receive from the time it sends the "I see the other spaceship start to accelerate" and the time that it sends the "We are docked" message.

And we can ask "How many pulses does the accelerating spaceship receive from the stationary spaceship from the time it turns on its engines until the time the two spaceships dock.

And we can point out that everyone agrees on these facts, including the planet-based observers.

And we can point out that the first number is lower than the second.

Other than that, we would need some more specific input on what your question was.
 
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  • #37
Dropout said:
What people are telling me is the special relativity party line I've heard 100 times before.

Another name for "the special relativity party line" is reality- it's passed all the experimental tests so far which is "all ye know of this world and all ye need to know".

That's why you've heard it 100 times before!
 
  • #38
"So, you see? No paradox. Ship B's captain thinks that A aged at 0.001 times his own rate as A moved towards him, while the Planet C observer thinks that B aged at 0.001 times A's rate after A decelerated, but it still makes sense for both of them to think that A will be 35.001000001 years old and B will be 36.0000005 years old when they meet, because B thinks that both him and A were 35 years old at the moment A accelerated, while C thinks that B was already 35.9999995 years old at the moment A accelerated, so even though A aged faster as B approached him, B was still older when they met because of this head start. There is no unique frame-independent truth about how old B was "at the same moment" that A turned 35 and accelerated, thus there can be no unique frame-independent truth about who "aged less" as A and B rushed towards each other."

It doesn't matter what planet C "THINKS" what will happen, as soon as A and B dock and transmit over the radio, the transmission will conflict with C's theory.
 
  • #39
In this experiment with 2 colony ships and a planet, I purposefully started and stopped the experiment with ShipA and ShipB in equal frames of reference so nobody could say, "Simultaneouty is why this or that happens."

It doesn't matter when, how fast, or how slow Planet C receives a radio transmission from ShipA or ShipB. A message is a message nomatter how slow it plays back, when you hear it, or how weak the signal is. If the radio message says at 0.000000000000000000000000000000001 normal speed that, "THE COLOR OF THE PEN IS BLUE!" Then the color of the pen is blue nomatter if the signal came out of a black hole, from a different galaxy, or was played backwards.
 
  • #40
Dropout said:
"So, you see? No paradox. Ship B's captain thinks that A aged at 0.001 times his own rate as A moved towards him, while the Planet C observer thinks that B aged at 0.001 times A's rate after A decelerated, but it still makes sense for both of them to think that A will be 35.001000001 years old and B will be 36.0000005 years old when they meet, because B thinks that both him and A were 35 years old at the moment A accelerated, while C thinks that B was already 35.9999995 years old at the moment A accelerated, so even though A aged faster as B approached him, B was still older when they met because of this head start. There is no unique frame-independent truth about how old B was "at the same moment" that A turned 35 and accelerated, thus there can be no unique frame-independent truth about who "aged less" as A and B rushed towards each other."

It doesn't matter what planet C "THINKS" what will happen, as soon as A and B dock and transmit over the radio, the transmission will conflict with C's theory.
No it doesn't. C's theory is that when they dock, A will be 35.001000001 years old and B will be 36.0000005 years old, which is exactly the same thing B predicted (and is what actually happens). Read my Step 1 and Step 2 from C's point of view to understand why he will predict this.
 
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  • #41
Dropout said:
In this experiment with 2 colony ships and a planet, I purposefully started and stopped the experiment with ShipA and ShipB in equal frames of reference so nobody could say, "Simultaneouty is why this or that happens."
I think you're confused here--just because everyone agrees that they share the same reference frame, that doesn't mean you can't analyze things from the perspective of a reference frame where both are moving at the same nonzero velocity. And if their ages are the same in their own rest frame, their ages will be different in a reference frame where they are moving.
Dropout said:
It doesn't matter when, how fast, or how slow Planet C receives a radio transmission from ShipA or ShipB. A message is a message nomatter how slow it plays back, when you hear it, or how weak the signal is. If the radio message says at 0.000000000000000000000000000000001 normal speed that, "THE COLOR OF THE PEN IS BLUE!" Then the color of the pen is blue nomatter if the signal came out of a black hole, from a different galaxy, or was played backwards.
How slow it plays back is indeed irrelevant, but when you hear it is not. Suppose in 2005 you look through your telescope and see an explosion 100 light years away--would you say that in your frame, the date the explosion happened was 2005? Of course not, you'd take into account the finite speed of light and retroactively assign it a date of 1905. Then if you saw another explosion in 2025 from a distance of 120 light years away, you'd say this explosion happened in 1905, and thus that the two explosions happened simultaneously in your frame. But if an observer in a different frame also assumes that light travels at the same speed in all directions in his frame, then he will assign different dates to these explosions, and say that they did not happen simultaneously.

It would also be possible to assign dates to events using only local measurements made right next to the event. Suppose I am sitting on a giant ruler which is at rest relative to me, and mounted along the ruler is a series of clocks, which are all "synchronized" in my frame (more on what this means in a second). Then if an explosion happens right next to the ruler, I can just look at what marking on the ruler this explosion happened next to, and what the reading on the clock at that marking was at the moment it happened. Another observer may also be riding on a ruler that's at rest relative to him, and which is moving parallel to my ruler alongside of it, so he can assign coordinates to the event using the same procedure. But the key here is that according to Einstein, each observer should "synchronize" the clocks along their own ruler using the assumption that light travels at the same speed in all directions in their own frame--but if each observer uses this assumption, than each observer will see the other observer's clocks as being out-of-sync. To see this, suppose I set off a flash at the exact midpoint of two clocks. If I assume light travels at the same speed in all directions in my frame, then I should define the clocks to be "synchronized" if each one reads the same time at the moment the light from the flash hits it. But if another observer who sees the two clocks moving also assumes light moves at the same speed in all directions in his frame, then from his point of view the light must hit the two clocks at different times, since one clock is moving towards the point where the flash was set off and the other is moving away from that point. So, if each clock reads the same time when the light hits it, this other observer will say the two clocks are out-of-sync (I drew some diagrams of two rulers moving alongside each other in this thread, illustrating how each one thinks the other one's clocks are running slower and are out-of-sync, yet they are consistent in their predictions about physical events in the same local neighborhood). The end result is that each observer will get the same result for the coordinates of different events if he relies on local measurements on a system of synchronized clocks that he would if he relied on the idea I outlined in the previous paragraph, where you look at the time you received light from an event and then subtract the time the light took to get to you. Either way, if two events (such as A and B celebrating their 35th birthday) happen "at the same time" in one frame, that means that in another frame the two events happened at "different times".
 
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  • #42
Dropout said:
In this experiment with 2 colony ships and a planet, I purposefully started and stopped the experiment with ShipA and ShipB in equal frames of reference so nobody could say, "Simultaneouty is why this or that happens."

It doesn't matter when, how fast, or how slow Planet C receives a radio transmission from ShipA or ShipB. A message is a message nomatter how slow it plays back, when you hear it, or how weak the signal is. If the radio message says at 0.000000000000000000000000000000001 normal speed that, "THE COLOR OF THE PEN IS BLUE!" Then the color of the pen is blue nomatter if the signal came out of a black hole, from a different galaxy, or was played backwards.

But simultaneity IS important to the problem, becaue the planet's notion of simultaneity is different from the ships notion of simultaneity.

You may have heard this 100 times before, but one can always hope that this time (the 101 time) that you will listen...

[add]
To explain a little further...

Let's suppose that A and B decide to make a big cerimonial event for the time when ship B lights its engines up.

A and B carefully synchorinze their clocks. Rather than worry about how this is accomplished, let's describe the result. When A sends a signal "It's now Jan 1, 2500 Ad", it arrives on ship B exactly on Jan 1, 2501 Ad, one year later. (One year later being the difference betweent the time contained in the transmission, based on A's clock, and the time it arrives, based on B's clock.)

Similarly, when B sends a signal to A, if they send the signal on Jan 1 2501 Ad (B's clock) iit will arrive on Jan 1, 2502 Ad (A's clock).

The planet will see things differently however - in the planet's coorinate system, A and B's clocks will not be synchronized. This is the key point that you've been missing.
 
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  • #43
JesseM said:
But unless we modify the laws of physics, there will be no way to measure what the ether's rest frame is. Also, see this usenet post for more reasons why this is an extremely inelegant solution.

I don't rate his views on the ether, as he misses key points. I posted a response to his work in an earlier link
https://www.physicsforums.com/archive/topic/t-58050_Aether_theories_which_are_experimentally_indistinguishable_from_SR..html [Broken]
about an important third class of ether, which Tom Roberts missed.

No one has yet put a good case to forward to dismiss the ether.
 
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  • #44
wisp said:
No one has yet put a good case to forward to dismiss the ether.
How 'bout - there is no evidence that it exists and our theories work extrordinarily well without it? Isn't that good enough reason not to pursue it?
 
  • #45
russ_watters said:
How 'bout - there is no evidence that it exists and our theories work extrordinarily well without it? Isn't that good enough reason not to pursue it?

Russ

No. I believe that the detection of the ether will become routine once techniques are developed to detect it using instruments of proper sensitivity. An article published in the New Scientist today "Catching the cosmic wind" explains how the ether wind can be measured. I believe there are simpler ways to detect the ether, but this method looks hopeful.
 
  • #46
wisp said:
Russ

No. I believe that the detection of the ether will become routine once techniques are developed to detect it using instruments of proper sensitivity...


wisp,

How sensitive do the instruments need to be? And can "sensitivity" be described in terms of the minimum variation in light speed that can be resolved?
 
<h2>1. What is general relativity?</h2><p>General relativity is a theory of gravity developed by Albert Einstein in the early 20th century. It describes how massive objects, such as planets, stars, and galaxies, interact with each other through the curvature of space and time.</p><h2>2. How does general relativity differ from Newton's theory of gravity?</h2><p>Newton's theory of gravity, also known as classical mechanics, describes gravity as a force between two objects. General relativity, on the other hand, explains gravity as the curvature of spacetime caused by the presence of massive objects.</p><h2>3. What are some practical applications of general relativity?</h2><p>General relativity has many practical applications, including predicting the orbits of planets and satellites, understanding the behavior of black holes, and providing the basis for the Global Positioning System (GPS).</p><h2>4. Is general relativity proven?</h2><p>General relativity has been extensively tested and is considered one of the most successful theories in physics. It has been confirmed by numerous experiments, observations, and predictions, but it is still an active area of research.</p><h2>5. Can general relativity be reconciled with quantum mechanics?</h2><p>Currently, there is no complete theory that unifies general relativity with quantum mechanics, which describes the behavior of particles at the subatomic level. This is a major challenge in modern physics and is an area of ongoing research.</p>

1. What is general relativity?

General relativity is a theory of gravity developed by Albert Einstein in the early 20th century. It describes how massive objects, such as planets, stars, and galaxies, interact with each other through the curvature of space and time.

2. How does general relativity differ from Newton's theory of gravity?

Newton's theory of gravity, also known as classical mechanics, describes gravity as a force between two objects. General relativity, on the other hand, explains gravity as the curvature of spacetime caused by the presence of massive objects.

3. What are some practical applications of general relativity?

General relativity has many practical applications, including predicting the orbits of planets and satellites, understanding the behavior of black holes, and providing the basis for the Global Positioning System (GPS).

4. Is general relativity proven?

General relativity has been extensively tested and is considered one of the most successful theories in physics. It has been confirmed by numerous experiments, observations, and predictions, but it is still an active area of research.

5. Can general relativity be reconciled with quantum mechanics?

Currently, there is no complete theory that unifies general relativity with quantum mechanics, which describes the behavior of particles at the subatomic level. This is a major challenge in modern physics and is an area of ongoing research.

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