The Twin Paradox can't be resolved.

In summary, Lorentz's theory states that time is always dilated. This means that even when two individuals, like Speedo and Goslo, start off at the same age, if one of them travels at high speeds, they will age slower than the other. This is known as the "twin paradox". However, from Speedo's point of view, both he and Goslo would see each other's clock ticking slower than their own for half of the trip and faster for the other half. This is due to the time it takes for images to propagate. When Speedo returns to Earth, he would be much younger than Goslo, as seen from Goslo's perspective. This is because Goslo saw Speedo's
  • #71
Whovian said:
Still please note that if the Earth were replaced by a point (which won't happen, but for the sake of example let's assume it did,) that point would be a completely inertial reference frame, despite the fact that it's orbiting the Sun, one of the primary postulates of General Relativity.

No, that's not completely correct. Freefall is only equivalent to inertial motion in a limiting sense: An experiment conducted in freefall will give the same result as the same experiment conducted in an inertial frame, provided that tidal effects can be ignored (that is, the variation of gravity with location). That's probably true for most experiments that you might perform in a falling elevator, but is definitely not true if the experiment involves orbits.
 
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  • #72


ghwellsjr said:
Yes, I am taking for granted the source-independence of light [speed] because that part of Einstein's second postulate is measurable and proven to be true.

You're taking more than that for granted. Your Doppler analysis tacitly assumes not only that the speed of light is independent of the source, but that it is the same in all directions in terms of coordinates in which the laws of Newtonian mechanics hold good (to the first approximation). If this were not true, none of the relativistic effects would occur. It is indispensable in the derivation of all relativistic effects. Try giving your Doppler explanation assuming light propagates at a speed independent of the source but has a different speed in different directions in terms of coordinates such that the laws of mechanics hold good. You will not get any asymmetric aging.

Of course, it would be possible to derive the Doppler explanation in such terms, but only by introducing the requisite compensatory effects due to the use of those coordinates, so this really doesn't save you from needing to account for the full premises and effects of special relativity, one way or another. It is exactly like claiming that classical mechanics can dispense with the principle of inertia because we can use non-inertial coordinates to describe phenomena. The fallacy of the argument is that, when such non-inertial coordinates are used, it is necessary to include compensatory terms (e.g., fictitious forces) which are simply defined based on the deviation of the non-inertial coordinates from the inertial coordinates. So it doesn't really avoid the reliance on the principle of inertia, it just disguises the reliance.

ghwellsjr said:
So now would you agree that based solely on Einstein's first postulate of the Principle of Relativity and the principle of the source-independence of light but ignoring the rest of Einstein's second postulate and without establishing any frame of reference, we can determine that the Doppler factors for approaching and retreating at the same relative speed are reciprocals of one another and from this alone we can determine that Goslo ages more than Speedo by the factor gamma?

No, you've only gotten part-way there. You've now accepted the need for the light-speed postulate to the extent that you must invoke source-independence (good!), but you still need to understand that you are also assuming directional independence in terms of coordinates in which the laws of mechanics hold good, and moreover you are assigning the specific value of c to that source-independent and direction-independent quantity (to give actual numerical predictions). In other words, you are invoking Einstein's second postulate (along with the relativity postulate). This shouldn't surprise you. It's obvious that relativistic effects (such as asymmetric aging of the twins) do not follow simply from the principle of relativity.
 
  • #73
ghwellsjnr said:
stevendaryl said:
Well, that's the issue: why must it be an inertial frame of reference? Why can't it be a "piecewise inertial" frame of reference? That is, why can't you use

τ= ∫√(1-(v/c)2 dt

where t is proper time for the "traveling" twin, and v is the speed of the "stay-at-home" twin relative to the instantaneous rest frame of the traveling twin? You can't because there are pieces of the worldline of the stay-at-home twin that are left unaccounted for. (In the Euclidean analog, the problem is that there are pieces of the path of the "straight" road that are counted twice by the corresponding formula for length).
That formula is defined for an inertial Frame of Reference. Its definition is not applicable to a noninertial frame.
The proper length is frame independent. The formula above can be used to calculate the proper time of any worldline, inertial or not.
 
  • #74
Mentz114 said:
Originally Posted by stevendaryl: "Well, that's the issue: why must it be an inertial frame of reference? Why can't it be a "piecewise inertial" frame of reference? That is, why can't you use

τ= ∫√(1-(v/c)2 dt

where t is proper time for the "traveling" twin, and v is the speed of the "stay-at-home" twin relative to the instantaneous rest frame of the traveling twin?"

Originally Posted by ghwellsjnr: "That formula is defined for an inertial Frame of Reference. Its definition is not applicable to a noninertial frame."

The proper length is frame independent. The formula above can be used to calculate the proper time of any worldline, inertial or not.

You're both right. The formula can be applied to any worldline, but only if v and t are defined in terms of a single standard inertial system of space and time coordinates.
 
  • #75
Mentz114 said:
The proper length is frame independent. The formula above can be used to calculate the proper time of any worldline, inertial or not.

The issue is not whether the worldline is inertial, but whether an inertial frame is used to compute the t and v appearing in the integral:

τ= ∫√(1-(v/c)2 dt

What doesn't work is the following:
Let t be the proper time of one observer O1.
Let v(t) be the speed of a second observer O2, as measured in a frame in which O1 is instantaneously at rest.

Then the above integral does not give you the age of O2, except in the case where O1 is inertial.
 
  • #76
stevendaryl said:
The issue is not whether the worldline is inertial, but whether an inertial frame is used to compute the t and v appearing in the integral:

τ= ∫√(1-(v/c)2) dt

What doesn't work is the following:
Let t be the proper time of one observer O1.
Let v(t) be the speed of a second observer O2, as measured in a frame in which O1 is instantaneously at rest.

Then the above integral does not give you the age of O2, except in the case where O1 is inertial.
OK, because worldlines have to be parameterized by a clock time, the formula requires that t is the time on a clock and in SR, t and proper time are the same in the rest frame of an inertial observer. None of this detracts from the proposition that the invariant proper length of a worldline can be found.

(Thanks to Samshorn also)

I think it's probably time for me to shut-up and calculate. I might try the calculation you outline.
 
Last edited:
  • #77
stevendaryl said:
ghwellsjr said:
That formula is defined for an inertial Frame of Reference. Its definition is not applicable to a noninertial frame..
Uh, that's what I said. The point of my post was to explain what goes
wrong if you try to use it in a noninertial frame, to give a feel for why it doesn't work in noninertial frames.
In which post did you mention anything about a definition?
stevendaryl said:
ghwellsjr said:
But again, my complaint about your analogy is that when you say that one traveler can look over at the other one and see how far he has progressed, it gives the impression that Speedo can look over at Goslo and see how far he has progressed, meaning, of course, where he is at any particular time, but he can't do that.
It's almost never the case that we understand what's going on in the world
by just looking. Looking gives us information which we then have to piece
together to get the complete story. You can certainly, after the fact,
compute the quantity:

T_1(t) = the age of twin 1 at the time twin 2 has age t, as measured in the
frame in which twin 2 is instantaneously at rest.

and

T_2(s) = the age of twin 2 at the time twin 1 has age s, as measured in
the frame in which twin 1 is instantaneously at rest.

Then these quantities will satisfy

dT_1/dt = square-root(1-(v/c)2)
where v is the speed of twin 1 as measured in the frame in which twin 2 is at rest, and

dT_2/dt = square-root(1-(v/c)2)
where v is the speed of twin 2 as measured in the frame in which twin 1 is at rest,

except during times of acceleration.
Instead of pointing out that an arbitrary definition is required to analyze, compare, contrast or otherwise make any statements about remotely located clocks, you (and Jonathan Scott) talk only about making measurements, as if we can learn the truth about such matters if only we are smart enough to apply the correct interpretation. I have repeatedly said that you will make whatever measurements follow from your arbitrary definition of how the measurements should be made and that is a valid exercise but you should not conclude that it is any more correct or meaningful than the measurements made from any other arbitrary definition.

By the way, I don't understand your calculation procedure quoted above or why you put in the acceleration exception, but it doesn't matter, I continue to affirm that a well-defined process for dealing with remote times is perfectly valid. I'm not arguing that, simply that it's just one of an infinite number of arbitrary definitions. But every one of them will agree with what Speedo sees of Goslo's clock and that is the one thread of consistency between them all and it is most easily analyzed using Relativistic Doppler. No other analysis provides any additional insight into what is actually happening.
 
  • #78
stevendaryl said:
The issue is not whether the worldline is inertial, but whether an inertial frame is used to compute the t and v appearing in the integral:

τ= ∫√(1-(v/c)2 dt

What doesn't work is the following:
Let t be the proper time of one observer O1.
Let v(t) be the speed of a second observer O2, as measured in a frame in which O1 is instantaneously at rest.

Then the above integral does not give you the age of O2, except in the case where O1 is inertial.

Mentz114 said:
OK, because worldlines have to be parameterized by a clock time, the formula requires that t is the time on a clock and in SR, t and proper time are the same in the rest frame of an inertial observer.
I would say this formula doesn't work for in noninertial frames because it assumes the standard pseudo-Euclidean metric. It should work, if you use the appropriate metric for the non-inertial frame. For example the Rindler line element for a frame with uniform proper acceleration g:

fadc81489c4e3933a1a392d9af6dad27.png
 
  • #79
ghwellsjr said:
In which post did you mention anything about a definition?

I just meant that the formula cannot be used (without modifications) in a noninertial frame.

ghwellsjr said:
By the way, I don't understand your calculation procedure quoted above or why you put in the acceleration exception, but it doesn't matter, I continue to affirm that a well-defined process for dealing with remote times is perfectly valid. I'm not arguing that, simply that it's just one of an infinite number of arbitrary definitions. But every one of them will agree with what Speedo sees of Goslo's clock and that is the one thread of consistency between them all and it is most easily analyzed using Relativistic Doppler. No other analysis provides any additional insight into what is actually happening.

I disagree whole-heartedly. Whether something provides insight or not is a matter of opinion, of course, but I believe that it can be very helpful to look at things from a wide variety of viewpoints.
 
  • #80
stevendaryl said:
ghwellsjr said:
But every one of them will agree with what Speedo sees of Goslo's clock and that is the one thread of consistency between them all and it is most easily analyzed using Relativistic Doppler. No other analysis provides any additional insight into what is actually happening.
I disagree whole-heartedly. Whether something provides insight or not is a matter of opinion, of course, but I believe that it can be very helpful to look at things from a wide variety of viewpoints.
I agree that additional analyses from a wide variety of viewpoints can be very helpful, if by that you mean they all agree on what is actually happening--they all agree on what Speedo sees of Goslo's clock and vice-versa--but not if you mean they all provide additional (and divergent) information of what is actually happening. That's the whole point of Special Relativity, you can analyze the same scenario from different reference frames and they all agree on what is actually happening--they don't purport to make any other claims on what is actually happening.
 
  • #81


Samshorn said:
ghwellsjr said:
So now would you agree that based solely on Einstein's first postulate of the Principle of Relativity and the principle of the source-independence of light but ignoring the rest of Einstein's second postulate and without establishing any frame of reference, we can determine that the Doppler factors for approaching and retreating at the same relative speed are reciprocals of one another and from this alone we can determine that Goslo ages more than Speedo by the factor gamma? And would you agree that this analysis directly answers Michio Cuckoo's question in post #1?
No, you've only gotten part-way there. You've now accepted the need for the light-speed postulate to the extent that you must invoke source-independence (good!), but you still need to understand that you are also assuming directional independence in terms of coordinates in which the laws of mechanics hold good, and moreover you are assigning the specific value of c to that source-independent and direction-independent quantity (to give actual numerical predictions). In other words, you are invoking Einstein's second postulate (along with the relativity postulate). This shouldn't surprise you. It's obvious that relativistic effects (such as asymmetric aging of the twins) do not follow simply from the principle of relativity.
I'm talking about the physics of the world we live in. It is not necessary to postulate the directional independence of light to show that the Doppler factors for approaching and retreating are reciprocals of each other. In fact, prior to Einstein, with the belief in an absolute but unidentifiable ether in which light propagates at c, so that Speedo and Goslo are traveling through the ether at a constant speed so that light does not take the same time to go between them in different directions, they still will measure their Doppler shifts to be equal when retreating and equal when approaching and they can prove that these two factors will be the inverse from each other. A science does not need to establish a frame of reference with previously synchronized clocks based on the postulate that light takes the same time to get from A to B as it does to get from B to A to determine that these facts would be true. In other words, it works just as well with the postulate that there exists an absolute ether.
 
  • #82
I copy below a file, but the figure may not show up.
Relativistic aging
Very briefly I will present my understanding of relativistic aging.

Special relativity (SR): (“Moving” below means motion at a constant speed along a straight line.)

(1) If we observe an object moving past us with a certain velocity u, it will appear contracted in the direction of its motion by a factor √(1 – u2/c2), where c is the sped of light.

(2) If we observe a clock moving past us with a certain velocity u, it will appear to be losing time, and its rate will be slowed down by a factor 1/√(1 – u2/c2), where c is the sped of light.

(3) If we move with the object and the clock, we measure no length contraction and no time dilatation. Meson example: if we ride with cosmic mesons coming down, we will detect no changes in their lifespan; if we stand on the ground and observe the mesons coming down, we will detect prolonged lifespan.

(4) If Observer A is moving relative to Observer B with speed u, then Observer B is moving relative to Observer A with -u. Because of u2, the direction of u is irrelevant. To each observer, other’s clock appears to be losing time. No relative aging here. (Same logic applies to lengths.)

General relativity (GR): Gravitation is due to the curvature which matter (or antimatter) creates in the field of space-time geometry. The field of space-time geometry is the gravitational field. Particles follow space-time geodesic lines of the field. Why and how matter warps space and time are left unexplained! Remember: there is one and only true theory that can explain and describe gravitational wave/pulse and its structure, speed, and polarization; this is the ultimate test of any gravity theory. Astronomic collisions and interactions among celestial bodies notwithstanding, so far there is no evidence of waves/pulses (or gravitons) in the field of space-time geometry.

(1) A particle vibrates at lower frequency closer to a mass (or in a stronger gravitational field).

(1 a) If the frequency is that of emitted light, spectral lines produced at a mass are redshifted compared to those produced at infinity. That is, emitted spectral wavelengths are longer closer to the mass.

(1 b) If the vibrating particle serves as an atomic clock, its time period is longer at the mass than at infinity. That is, time runs slower closer to the mass.

(1 c) At a black hole, it can be easily deduced from the above that light travels at c but with a virtually flat waveform and the atomic clock’s time run virtually stops.

(1 d) When no mass is present anywhere (absurd but assume it anyway), time is meaningless. At the center of a mass, time is meaningless.

(2) A thin material rod is longer closer to a mass (or in a stronger gravitational field). The rod is deformed in a non-uniform gravitational field.

(2 a) At a black hole, the rod flattens to the point where it disintegrates.

(3) The effects of other fundamental fields (the strong, the weak, and electromagnetic) on time are not known.

Principle of equivalence (PE). Specific thought experiments reveal that there is a pseudogravity in the direction opposite to an applied acceleration. This is a just a pseudo (as if) gravity, not a fundamental-force gravity! I am not aware of any experimental evidence of such a pseudogravity affecting time and length. (Thought experiments are good to have but they can’t be substitutes for real experiments. Sadly, some of the thought experiments have become reality for most physicists. Under the Pseudogravity thread, I made statements on acceleration, weightlessness, and centrifugal force, et al. Please review them.)

Relativistic aging.

(1) A physicist on the first floor of a tall building has a twin sister manager on the top floor. Per GR, the physicist ages more slowly than the manager. (Now you know why I sit at the ground floor.)

(2) Two brothers decide to determine whether SR and GR could help guide them age slowly. Older brother Resto stays at Earth; younger brother Speedo goes on a journey into deep space. They have devised a plan for traveling from Earth to Planet P, which is comparatively quite massive. See the figure below.

[Unable to copy the Figure here.]

Speedo departs Earth at acceleration aE from point E to point A and achieves velocity u with which he continues to Planet P. After 10 years, he reaches close to Planet P. He accelerates at aP from B to P to gain sufficient speed to orbit the planet safely. He orbits for 5 years. He decelerates at aP to speed u from P to B, continues toward the earth, decelerates at aE from A to E to touchdown. He meets his brother Resto. Does Resto find Speedo younger or older?

E to A: No changes in Speedo’s clock due to the applied acceleration (no experimental proof). His atomic/biological clock speeds up as Earth’s gravity gets weaker.

A to B: The speed is uniform; so, according to SR, the brothers age at the same rate relative to each other. Per GR, the clock speeds up as Earth’s gravity gets weaker but slows down as P’s gravity gets stronger.

B to P: No changes in Speedo’s clock due to the applied acceleration (no experimental proof). His atomic/biological clock slows down as P’s gravity gets stronger.

Orbiting P: Speedo’s clock is slower compared to what it was at Earth due to stronger gravity. For 5 years he ages at a slower rate.

P to B: No changes in Speedo’s clock due to the applied deceleration (no experimental proof). His atomic/biological clock speeds up as the P’s gravity gets weaker.

B to A: The speed is uniform; so, according to SR, the brothers age at the same rate relative to each other. Per GR, the clock speeds up as P’s gravity gets weaker but slows down as Earth’s gravity gets stronger.

A to E: No changes in Speedo’s clock due to the applied deceleration (no experimental proof). His atomic/biological clock slows down as Earth’s gravity gets stronger.

The journey’s summary. Any gain/loss during the outward journey from E to P is canceled by the loss/gain during the return journey from P to E. So, ultimately Speedo gets younger but only during the time he orbited the heavier Planet P. Only the difference between Planet P’s gravity and Earth’s gravity contributes to Speedo’s age.
 
  • #83
I have a whole list of slight disagreements with your writeup. My general complaint is that whether one clock ticks at a faster or slower rate than another clock is dependent on a choice of a coordinate system. It's not relative to an observer, it's relative to a coordinate system. In Special Relativity, we can (often) ignore the difference, because we can associate an (inertial) coordinate system with each observer. But in General Relativity, no coordinate system is inertial over an extended region, and there is no unique way to pick a coordinate system for an observer. This is relevant to the question of whether one observer's clock is "ticking faster" than another clock, because to make such a claim requires figuring out "What time tA does clock A show when clock B shows time tB?" To answer such a question requires a coordinate system (at least, a way of determining which events are simultaneous).

Anyway, your thought experiment involves both rockets and gravity, so it's a question for General Relativity. Assuming that the rocket itself is small enough that we don't have to worry about its effect on spacetime curvature, GR gives the following answer for how old a person will be after taking a rocket trip:

τ = ∫√(guv dxudxv)

where guv is the metric tensor and dxu is the change in coordinate xu along the trip. Assuming that all speeds are pretty small compared with the speed of light, and that the only relevant mass is the mass of the Earth (whose gravity is pretty mild), then we can use the following approximation (using Schwarzschild coordinates)

τ = ∫ (1 - GM/(c2r) - 1/2 (v/c)2) dt

For Resto, r is constant, and is equal to R, the radius of the Earth, and v=0 (let's ignore the rotation of the Earth). So
τRESTO = (1-GM/(c2 R)) t

For Speedo, we can simplify things by assuming that he very quickly gets far enough away that the Earth's gravity is irrelevant, and that he spends most of his time traveling at some constant speed v. In that case,

τSPEEDO = (1-1/2 (v/c)2) t

This is the slow-speed approximation to the SR result τ = √(1- (v/c)2) t

So which twin ages the most depends on the relative sizes of -GM/R and -1/2 (v/c)2
 
  • #84
Well, I read the posts after mine on Relativistic aging. Too many situations have been mixed up for this issue to be resolved. Thanks anyway.
 
  • #85


ghwellsjr said:
It is not necessary to postulate the directional independence of light to show that the Doppler factors for approaching and retreating are reciprocals of each other.

You didn't read what I wrote. Special relativity (with relativistic Doppler, asymmetric aging of twins, etc) isn't based on "directional independence of light speed" (a meaningless phrase, like one hand clapping), it is based on directional independence (indeed, the complete invariance) of light speed in terms of coordinates in which the homogeneous and isotropic laws of mechanics hold good. Do you see the difference? This proposition, from which all the uniquely relativistic phenomena follow, has been abundantly confirmed by experiment.
 
  • #86
SinghRP said:
Very briefly I will present my understanding of relativistic aging.

Special relativity (SR): (“Moving” below means motion at a constant speed along a straight line.)

(1) If we observe an object moving past us with a certain velocity u, it will appear contracted in the direction of its motion by a factor √(1 – u2/c2), where c is the sped of light.

(2) If we observe a clock moving past us with a certain velocity u, it will appear to be losing time, and its rate will be slowed down by a factor 1/√(1 – u2/c2), where c is the sped of light.

(3) If we move with the object and the clock, we measure no length contraction and no time dilatation. Meson example: if we ride with cosmic mesons coming down, we will detect no changes in their lifespan; if we stand on the ground and observe the mesons coming down, we will detect prolonged lifespan.

(4) If Observer A is moving relative to Observer B with speed u, then Observer B is moving relative to Observer A with -u. Because of u2, the direction of u is irrelevant. To each observer, other’s clock appears to be losing time.

Up to there is fine.

No relative aging here.

That is wrong. You are right that the fact that the speed enters a the square means the sign doesn't matter but that doesn't imply "no relative aging", it means each sees the other as aging more slowly, as you said, each considers that the other's clock is running too slowly.

In order to compare the overall effect, you need to bring them back together so one will have to accelerate and that breaks the symmetry. The one that accelerates has aged least when the meet.
 
<h2>1. What is the Twin Paradox and why is it considered unsolvable?</h2><p>The Twin Paradox is a thought experiment in which one twin travels at high speeds in space while the other stays on Earth. When the traveling twin returns, they are younger than the twin who stayed on Earth. This paradox is considered unsolvable because it challenges our understanding of time and the concept of relativity.</p><h2>2. Can the Twin Paradox be resolved using current scientific theories?</h2><p>Yes, the Twin Paradox can be resolved using the theory of special relativity. According to this theory, time slows down for objects in motion relative to an observer. This explains why the traveling twin returns younger than the stationary twin.</p><h2>3. Are there any real-life examples of the Twin Paradox?</h2><p>Yes, there are real-life examples of the Twin Paradox. For instance, astronauts who travel in space at high speeds experience time dilation and return to Earth slightly younger than their counterparts who stayed on Earth.</p><h2>4. Is there any ongoing research or experiments being conducted to resolve the Twin Paradox?</h2><p>Yes, there is ongoing research and experiments being conducted to further understand the Twin Paradox and its implications. Scientists are using advanced technologies, such as atomic clocks, to measure time dilation and test the predictions of special relativity.</p><h2>5. Can the Twin Paradox be resolved through a change in perspective or frame of reference?</h2><p>No, the Twin Paradox cannot be resolved through a change in perspective or frame of reference. This paradox is a fundamental concept in the theory of special relativity and is not dependent on the observer's point of view.</p>

1. What is the Twin Paradox and why is it considered unsolvable?

The Twin Paradox is a thought experiment in which one twin travels at high speeds in space while the other stays on Earth. When the traveling twin returns, they are younger than the twin who stayed on Earth. This paradox is considered unsolvable because it challenges our understanding of time and the concept of relativity.

2. Can the Twin Paradox be resolved using current scientific theories?

Yes, the Twin Paradox can be resolved using the theory of special relativity. According to this theory, time slows down for objects in motion relative to an observer. This explains why the traveling twin returns younger than the stationary twin.

3. Are there any real-life examples of the Twin Paradox?

Yes, there are real-life examples of the Twin Paradox. For instance, astronauts who travel in space at high speeds experience time dilation and return to Earth slightly younger than their counterparts who stayed on Earth.

4. Is there any ongoing research or experiments being conducted to resolve the Twin Paradox?

Yes, there is ongoing research and experiments being conducted to further understand the Twin Paradox and its implications. Scientists are using advanced technologies, such as atomic clocks, to measure time dilation and test the predictions of special relativity.

5. Can the Twin Paradox be resolved through a change in perspective or frame of reference?

No, the Twin Paradox cannot be resolved through a change in perspective or frame of reference. This paradox is a fundamental concept in the theory of special relativity and is not dependent on the observer's point of view.

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