How does the Twins Paradox challenge our understanding of ageing?

In summary, a biology teacher is discussing the effects of traveling at speed on ageing with physics teachers. They explain that time passes more slowly for objects traveling at speed and that speed and time are relative to the frame of reference of the observer. However, the biology teacher still struggles to understand how the twins paradox results in one twin aging more than the other due to traveling at the speed of light. The physics teachers simplify the concept by comparing it to tossing a ball in a moving car and emphasize the importance of understanding simultaneity.
  • #71
Al68 said:
The change in the period of the oscillator occurs because of a change in relative velocity between oscillator and reference frame, whether or not the oscillator accelerates.


We have to be careful on the word here. You can not get velocity without acceleration.

Is it the velocity that alters that state of the clock or is it the acceleration that alters the state of the clock? What experiment can we do to measure which is responsible? Two things happen and a third is found to be correlated. If you can never separate the two things how will you ever be able to call one the cause and the other not the cause?
 
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  • #72
Al68 said:
It may be more intuitive, but it's conceptually wrong. Each twin ages 1 year per year of elapsed time. Again, it's time itself that "flows" differently in different frames, not a change in the operation of various devices used to measure it.
Time itself ... flows differently??

The traveller, and all other observers, watched the earth-sun system rotate 20 times during the trip. Yet the traveller and his clock only ticked off 5 years.

We agree that difference in tick rate is due to difference in velocity, don't we? It seems clear to me from experiments that it isn't intervals of constant, uniform velocity that exhibit tick rate changes, but intervals of acceleration.

Al68 said:
... different results do not imply a difference in the measuring device itself.
In this case they do.
 
  • #73
edpell said:
We have to be careful on the word here. You can not get velocity without acceleration.

Is it the velocity that alters that state of the clock or is it the acceleration that alters the state of the clock? What experiment can we do to measure which is responsible? Two things happen and a third is found to be correlated. If you can never separate the two things how will you ever be able to call one the cause and the other not the cause?

This may have been gone over before ... but kindly humour me.

If there was a clock on the traveling ship and a similar clock at the stationary take off location - say they are old grandfather clocks .. with swinging pendulums as a driving force. (the sort of things that Galileo worked with). Let us suppose there is a way to track the swing of the pendulum in the ship, but at the point of origin.

Would the swing of the pendulum on the ship match that of the clock at the stationary place? OR If it moved one centimetre in its' swing would it take less time than for the stationary clock's pendulum to move the same distance?

I guess this is a classical physics question being applied to a quantum physics situation.

Oh - by the way: look for the Bengals to take less time to move the football over the Jets goal line and do it more often than the Jets can do the reverse this afternoon. :devil:
 
  • #74
ThomasT said:
The traveller, and all other observers, watched the earth-sun system rotate 20 times during the trip. Yet the traveller and his clock only ticked off 5 years.

NO!

This case seems to have gamma of 4. So the traveler only saw 5 rotations of the Earth around the sun when he/she looked in their telescope. Due to the fact that the light from rotations 6-20 has not yet reached the traveler. The traveler will have to keep looking for another 15 years (after arrival) to see the light from rotations 6-20.
 
  • #75
ThomasT said:
Time itself ... flows differently??

The traveller, and all other observers, watched the earth-sun system rotate 20 times during the trip. Yet the traveller and his clock only ticked off 5 years.
No, the traveler watched the Earth-Sun make .9 rotations during the trip. (Relativistic Doppler effect). From his reckoning, figuring in his relative velocity with respect to the Solar system, The Earth-Sun has made 0.635 rotations. He now stops at the destination (assume a short enough time of deceleration that he is, in all intents and purposes, stops dead. He is seeing the same light as he was before he decelerated, but his reckoning of how much time has passed on Earth changes. He is now 19.365 ly from Earth, which means that the information is 19.365 years old. Therefore, by his reckoning the Earth has aged 20 yrs since he left.
We agree that difference in tick rate is due to difference in velocity, don't we? It seems clear to me from experiments that it isn't intervals of constant, uniform velocity that exhibit tick rate changes, but intervals of acceleration.

Let's try to explain this by way of analogy:

You have two men(A&B) walking in the Same direction at the same speed on a featureless plain.
If you consider the direction they are walking as "time", this represents our twins At the starting point, at rest we each other. They each progress through time at the same rate and age at the same rate.

Now one man(B) turns and starts to walk in a new direction. As each walks in his own direction, they get further apart, or as each progresses through time, the distance increases between them. This represents one of the twins while traveling away from his other twin.

Now consider the perspective of man A. As he walks, B falls further behind with respect to the direction that A is walking. This represents B progressing through time more slowly or aging less than A.

But now consider man B. By his perspective, it is A that it falling behind. and he is just as entitled to claim that the direction that he is walking is the direction of time progression, and that it is A that is making slower progress/aging slower. This is the whole point behind the principle of Relativity. Each inertial frame judges other with respect to itself and there is no absolute reference. Each judges time progression as progress in the direction he is walking.

Now consider what happens when Man B turns to walk in the same direction as A again. This represents the traveling twin reaching his destination and stopping. The distance between them no longer changes, and they are again "at rest" with respect to each other.

From A's perspective, this just means that B stops losing ground, and starts to age at the same rate. He doesn't make up lost ground, however, and his total progression through time remains less. He remains younger.

From B's perspective, as he turns, A's position with respect to Him changes. He goes from being behind to being in front. (Stand in the middle of the room with an object to one side and slightly behind you. Now turn 45° in that direction. The object, from your perspective moves from behind you to in front of you.)

After B completes his turn, He finds that A is now ahead of him in time, and progressing at the same speed. His has made more progression through time. His has aged more and is older.

Both men agree in the final result, but have different views of how that result came to be. And this is the important part: Each man's view of what happened is just as valid at the others.

So when you ask what causes one twin to be older than the other at the end of the trip, the answer is: It depends on which twin you are.

Relativity makes us rethink how we measure time. To use the direction analogy again: Before Relativity, we could think of time as the direction North. No matter who you asked and what relative directions they where facing, they all agreed on what direction North was. Ask them to point North, and they all point the same direction. It is, in a sense an absolute direction.

Relativity tells us however that time is like the the direction Left. Ask a number of people to point left, and they will all point in different directions depending on the relative directions they are facing. There is no absolute "left". Left is determined by the individual and moves with him. And in Relativity, time measurement is determined by what frame you measure it from.
 
  • #76
edpell said:
NO!

This case seems to have gamma of 4. So the traveler only saw 5 rotations of the Earth around the sun when he/she looked in their telescope. Due to the fact that the light from rotations 6-20 has not yet reached the traveler. The traveler will have to keep looking for another 15 years (after arrival) to see the light from rotations 6-20.
The difference in time between the two frame has nothing to do with the light travel time. SR says that even after you take into account those effects, the time elapsed between two events is different in the two frames. Also, in the twin paradox problem, the traveller's twin aged twenty years, so the traveller would see the Earth going around the Sun twenty times during the trip. You're thinking of a different situation.

Wikipedia has a good explanation of the twin paradox from the traveling twin's point of view.

http://en.wikipedia.org/wiki/Twin_paradox#Resolution_of_the_paradox_in_special_relativity
 
  • #77
ThomasT said:
the physical fact is that only one clock ran slow
If two surveyors were to measure the distance along routes from New York to Miami, and one surveyor's route went through Washington DC and the other surveyor's route went through Los Angeles, would you say "the physical fact is that only one surveyor's chain was shrunk" or would you say "the physical fact is that only one surveyor's route was longer"? In other words, would you attribute the difference in measurement to a difference in the thing being measured or to a difference in the thing doing the measuring?
 
  • #78
edpell said:
We have to be careful on the word here. You can not get velocity without acceleration.

Is it the velocity that alters that state of the clock or is it the acceleration that alters the state of the clock? What experiment can we do to measure which is responsible? Two things happen and a third is found to be correlated. If you can never separate the two things how will you ever be able to call one the cause and the other not the cause?
Actually, it is neither velocity nor acceleration (both vector quantities), it is speed (a scalar quantity). Although you cannot have acceleration without a change in velocity you can have acceleration without a change in speed. This experiment has been done with accelerations on the order of 1018 g, and the results are that the time dilation is not a function of the acceleration.
 
  • #79
adw73uk said:
Hi, I'm a Biology teacher, constantly getting into discussions with the physics teachers at my school regarding the effect of traveling at speed on ageing.

This isn't exactly chemistry, but the following fact may provide insight. Consider a macroscopic "Bohr Atom," consisting of a resting, massive, positively charged central body orbited at constant speed in a circle by an equal magnitude negatively charged particle. For a given satellite speed, mass and orbital radius, one can readily calculate what the common magnitude charge must be. This system can be viewed from an alternate inertial frame, relative to which the central body moves with a constant velocity. When the electron's motion is computed relative to this second frame (using the laws of Maxwell, Lorentz and Newton) then the motion is a quasi-cycloid that cuts "above" and "below" the central body at distance R, but "in front of" and "behind" the central body at distance R/gamma. The computed motion also gives the result that the cycloid cycle time is (T)(gamma), where T=(2)(pi)(r)/(v). The interesting thing is that this is true no matter what inertial frame we initially assume the "atom" to be "at rest" in. Indeed, thanks to the way the clocks in the inertial frames are synchronized, each frame measures a moving "atom" to be length contracted. etc.! A more detailed account can be viewed at www.maxwellsociety.net/LovingLorentz.html[/URL]
 
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  • #80
DaveC426913 said:
Because one of them accelerated and the other didn't. That breaks the symmetry of relativity.

But doesn't that defeat the point of relativity? When you say one twin accelerated away, that's only relative to the other twin... but the exact opposite is true if you take the relative experience of the second twin. Relatively speaking, it's always the other twin that accelerated away.
 
  • #81
Accdeleration is not relative. One twin feels a kick in the seat of his pants as his spaceship engines fire, the other twin does not. The first twin knows, without having to look outside his spaceship at all, that he is not at rest (or moving at constant velocity) in an inertial reference frame.
 
  • #82
jtbell said:
Accdeleration is not relative. One twin feels a kick in the seat of his pants as his spaceship engines fire, the other twin does not. The first twin knows, without having to look outside his spaceship at all, that he is not at rest (or moving at constant velocity) in an inertial reference frame.

To say acceleration is not relative means you have already decided that one frame of reference is more absolute than the other. Though one twin experiences the other twin AND the universe accelerating away from him (hence the kick in the pants), while the other twin only experiences the first twin accelerating away... both experience the opposite twin accelerating away from them.

Also, being at rest is completely relative as well. Would you consider yourself at rest when typing your response to this on your computer? Because in reality you are rocketing through space on the Earth, and the Earth is swirling about the Milky Way, and who knows what else motions the entire universe is actually performing. But, in your current reference frame you are at rest... Everything is relative.
 
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  • #83
Hi Evolver, did you miss this part of jtbell's response:
One twin feels a kick in the seat of his pants as his spaceship engines fire, the other twin does not. The first twin knows, without having to look outside his spaceship at all

Nothing has to be decided in advance or with reference to the rest of the universe. An onboard accelerometer will suffice.
 
  • #84
DaleSpam said:
Hi Evolver, did you miss this part of jtbell's response:

Nothing has to be decided in advance or with reference to the rest of the universe. An onboard accelerometer will suffice.

I did not miss it, in fact I commented on it directly (please read above.) "The kick in the pants" you refer to is only unique to twin #1 because the entire universe around him is accelerating away from him (including twin #2). That is the only unique difference between twin #1 and twin #2, and that is what the on board meters are registering. Twin #2, nonetheless, still experiences twin #1 accelerating away from him... if this were not true twin #1 would never leave twin #2's reference frame.
 
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  • #85
Evolver said:
I did not miss it, in fact I commented on it directly (please read above.) "The kick in the pants" you refer to is only unique to twin #1 because the entire universe around him is accelerating away from him (including twin #2). That is the only unique difference between twin #1 and twin #2, and that is what the on board meters are registering. Twin #2, nonetheless, still experiences twin #1 accelerating away from him... if this were not true twin #1 would never leave twin #2's reference frame.
That's a lot of rot. It's been explained to you that only one twin in this scenario accelerates so it is not symmetrical as you insist.

JTBell and DaleSpam are far too polite to tell you - but you're being really stupid and arrogant.
 
  • #86
Mentz114 said:
That's a lot of rot. It's been explained to you that only one twin in this scenario accelerates so it is not symmetrical as you insist.

JTBell and DaleSpam are far too polite to tell you - but you're being really stupid and arrogant.

Actually this is a forum for discussion, so if you want to resort to name calling instead of discussing, perhaps this is not the place for you.

And as I have stated above, these are my ideas of the scenario... it is called the twin paradox for just that reason, it is a paradox... there is no cut and dry answer. So please stop assuming you have it. If anyone is being arrogant here it is you. There are multiple arguments for this paradox... for example Max von Laue argued that one twin was using two inertial frames and that switching inertial frames caused the difference, not acceleration at all. That is one of many many possibilities.

Science fails when ignorance dominates... and ignorance occurs when you have a closed mind. I never once said anybody was wrong or right, I was merely giving my thoughts on it. You on the other hand, assume to have the answer... and that makes you very dangerous for scientific discussion.
 
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  • #87
Evolver said:
Actually this is a forum for discussion, so if you want to resort to name calling instead of discussing, perhaps this is not the place for you.

And as I have stated above, these are my ideas of the scenario... it is called the twin paradox for just that reason, it is a paradox... there is no cut and dry answer. So please stop assuming you have it. If anyone is being arrogant here it is you.

It is not a paradox and its "resolution" is explained in most textbooks on relativity and countless times in this forum. There are plenty of people here who would be willing to provide the explanation but, perhaps like me, do not want to spend time trying to convince someone who has already decided that the "paradox" does not have a "resolution" easily explained within SR. If you cannot accept the universally accepted fact that acceleration is absolute, an important part of the explanation which shows that the scenario is not symmetrical as regards the twins, then there is no point in going any further.

Matheinste.
 
  • #88
matheinste said:
It is not a paradox and its "resolution" is explained in most textbooks on relativity and countless times in this forum. There are plenty of people here who would be willing to provide the explanation but, perhaps like me, do not want to spend time trying to convince someone who has already decided that the "paradox" does not have a "resolution" easily explained within SR. If you cannot accept the universally accepted fact that acceleration is absolute, an important part of the explanation which shows that the scenario is not symmetrical as regards the twins, then there is no point in going any further.

Matheinste.

Once again, the paradox arises from the interpretation of what is occurring, not the final outcome. The outcome remains the same and asymmetrical. Some like Von Laue chose to explain it as using multiple inertial frames, Einstein chose gravitational time dilation, Langevin said it was absolute acceleration that changed the direction of the velocity... all are asymmetrical in nature.

What you don't seem to get about my idea is that it IS NOT symmetrical, why you keep labeling it as such is beyond me. I say that both twins experience the other accelerating away from the other, but only twin #1 experiences the universe around him accelerating away. THAT IS NOT SYMMETRY.

Again, this is a forum for discussion and open thought, yet some of you have proven you do not accept that. Please then, don't comment on my posts, just ignore me. But before you do, please attempt to understand what I am saying and don't mislabel it. And as for your "textbook" comment... just remember that if Einstein had never dared to think outside the contexts of the textbooks of his day, there wouldn't even be a twin's paradox for us to debate about in the first place.
 
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  • #89
Evolver said:
To say acceleration is not relative means you have already decided that one frame of reference is more absolute than the other. Though one twin experiences the other twin AND the universe accelerating away from him (hence the kick in the pants), while the other twin only experiences the first twin accelerating away... both experience the opposite twin accelerating away from them.

Also, being at rest is completely relative as well. Would you consider yourself at rest when typing your response to this on your computer? Because in reality you are rocketing through space on the Earth, and the Earth is swirling about the Milky Way, and who knows what else motions the entire universe is actually performing. But, in your current reference frame you are at rest... Everything is relative.

Although no one frame is any more absolute than any other, the stay at home twin, along with the rest of the universe, can be considered, for our purposes, to be at rest in the same inertial frame of reference. The traveling twin does not remian in any inertial frame. There is a difference but neither is preferred or absolute.

Any observer/object in any reference frame is at rest with respect to that reference frame. I am at rest relative to the earth. But being on Earth I am not permanently at rest in any inertial reference frame as the Earth is accelerating. The Earth can be considered to be instantaneously at rest in a series of co-moving reference frames. But for purposes of illustration, thought experiments, the twin "paradox" etc. it is often considered to be at rest.

Matheinste.
 
  • #90
I want to go back to this previous comment, as I feel it is important to the discussion.
Evolver said:
To say acceleration is not relative means you have already decided that one frame of reference is more absolute than the other.

In SR there is indeed a special class of reference frames. We call this special class of reference frames "inertial". There are many equivalent ways to determine if a given reference frame is inertial or not, my favorite is that a reference frame is inertial if an ideal accelerometer at rest anywhere in the reference frame will always read 0.

The postulates of SR apply only to inertial reference frames. The traveling twin's frame is non-inertial, so they simply don't apply. The home twin's frame is inertial, and there are an infinite number of other inertial frames. By applying the standard formulas in any of those inertial reference frames you obtain the clear and unambiguous result that the traveling twin experiences less proper time.
 
  • #91
DaleSpam said:
I want to go back to this previous comment, as I feel it is important to the discussion.

In SR there is indeed a special class of reference frames. We call this special class of reference frames "inertial". There are many equivalent ways to determine if a given reference frame is inertial or not, my favorite is that a reference frame is inertial if an ideal accelerometer at rest anywhere in the reference frame will always read 0.

The postulates of SR apply only to inertial reference frames. The traveling twin's frame is non-inertial, so they simply don't apply. The home twin's frame is inertial, and there are an infinite number of other inertial frames. By applying the standard formulas in any of those inertial reference frames you obtain the clear and unambiguous result that the traveling twin experiences less proper time.

I fully understand and actually agree with everything you are saying. My question arises though out of the idea that inertial reference frames could theoretically be considered relative:

Take your example of the accelerometer. The traveler's will not read zero... if it is an accelerometer based on the Earthbound observer's reference frame. But if the accelerometer were calibrated to read zero as he "accelerated" from the Earthbound observer's perspective, you could say that he was at rest while the Earthbound person and the universe were rapidly accelerating away from him, and that would be the sudden jolt that he felt. And from the "traveler's" perspective the Earthbound person's accelerometer would not be reading zero.

And the reason the Earthbound observer didn't feel the jolt, was because he was traveling with the universe and therefore felt no discrepancy.
 
  • #92
Evolver said:
if the accelerometer were calibrated to read zero as he "accelerated" from the Earthbound observer's perspective
If you deliberately mis-calibrated it then it would certainly not be an ideal accelerometer. Similarly with ideal clocks and ideal rods.
 
  • #93
DaleSpam said:
If you deliberately mis-calibrated it then it would certainly not be an ideal accelerometer. Similarly with ideal clocks and ideal rods.

I wouldn't consider that mis-calibrating it though. It would be calibrating it to the proper reference frame. Otherwise you assume there is only one reference frame with which to calibrate them? Then of course the readings are always going to be in favor of that selected reference frame.

Much like the way they have to re-calibrate the clocks in satellites to make sure the GPS is accurate for the reference frame on Earth. They are adapting the one reference frame to suit the needs of their own. But there is no universal reference frame.
 
  • #94
In the twins scenario, would not the traveller's accelerometer, calibrated to read zero in any particular reference frame, exhibit different readings during different phases of the journey while the earthbound accelerometer would exhibit a constant reading.

Matheinste.
 
  • #95
Evolver said:
I wouldn't consider that mis-calibrating it though. It would be calibrating it to the proper reference frame.
Of course you wouldn't call it mis-calibrating and would prefer a more obfuscating term. However, the fact remains that such clocks, rods, and accelerometers certainly don't qualify as ideal. This includes the GPS clocks which are deliberately and carefully non-ideal.
 
  • #96
matheinste said:
In the twins scenario, would not the traveller's accelerometer, calibrated to read zero in any particular reference frame, exhibit different readings during different phases of the journey while the earthbound accelerometer would exhibit a constant reading.

Matheinste.

No, because think of this:

If they were both calibrated to read zero for their specific inertial frames, they would do just that. They are essentially calibrated at zero for their own frames, yet to the other twin they would appear to be accelerating at a constant rate.

Each twin would say the other is moving and that their accelerometer is merely inaccurate in showing that it reads zero. Also, there is some unique trait that the traveler exhibits in that he is not traveling with the universe as the Earthbound observer is. The Earthbound observer is embedded in the motion of the universe so notices no difference about its motion. The traveler has, in some way, utilized energy in a way that he broke free from the motion of the universe and watches as it accelerates away from him in his inertial frame.
 
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  • #97
DaleSpam said:
Of course you wouldn't call it mis-calibrating and would prefer a more obfuscating term. However, the fact remains that such clocks, rods, and accelerometers certainly don't qualify as ideal. This includes the GPS clocks which are deliberately and carefully non-ideal.

Don't qualify as ideal? For what, the sake of ease? The fact remains that if you choose to calibrate said clock, accelerator, whatever, with a certain frame of reference it will always produce inaccurate results when compared to a different frame of reference.

If you wish to get the true effect of every inertial frame you need instruments that function in, and are tuned to accurately display that frame of reference. You cannot assume there is a universal clock, rod, accelerator that should be taken as true for all inertial frames, it automatically makes the results biased to that frame.
 
  • #98
A correctly calibrated (ideal) clock, rod, or accelerometer is not tuned to a specific frame. It will work correctly in any reference frame (inertial or non-inertial, SR or GR, accelerating or not).

This conversation is getting rather silly. If you take any physics experiment and use mis-calibrated equipment you should not be surprised to obtain non-physical and non-sensical results. Garbage in garbage out.
 
  • #99
DaleSpam said:
A correctly calibrated (ideal) clock, rod, or accelerometer is not tuned to a specific frame. It will work correctly in any reference frame.

This conversation is getting rather silly. If you take any physics experiment and use mis-calibrated equipment you should not be surprised to obtain non-physical and non-sensical results. Garbage in garbage out.

Ok, we obviously have a base disagreement, which is perfectly fine and I respect your opinion. But what I'm saying is, the clocks and instruments you use to do your experiments on Earth, ARE garbage to other inertial reference frames.

The GPS satellite issue proves that. There can be no universally calibrated instrument, it's all subjective. The clocks on the satellite are perfectly functioning clocks... as are those on Earth. But, because of Relativity they must be adjusted for in order for the information passing between the two reference frames to be accurate. If not, the GPS data would be drastically off here on Earth.
 
  • #100
Evolver said:
But what I'm saying is, the clocks and instruments you use to do your experiments on Earth, ARE garbage to other inertial reference frames.
No, an ideal clock correctly measures proper time in all reference frames. It does not provide a garbage measurement in any frame.

This is not restricted to inertial reference frames nor is it restricted to inertially moving clocks. It applies for all reference frames and it applies to clocks undergoing any sort of motion.

Similarly with ideal accelerometers which measure proper acceleration in all reference frames.
 
  • #101
DaleSpam said:
No, an ideal clock correctly measures proper time in all reference frames. It does not provide a garbage measurement in any frame.

This is not restricted to inertial reference frames nor is it restricted to inertially moving clocks. It applies for all reference frames and it applies to clocks undergoing any sort of motion.

Similarly with ideal accelerometers which measure proper acceleration in all reference frames.

I completely understand what you're saying, and I agree with it in theory. I guess what I'm not convinced of is that such a device can exist. How could anyone device be deemed reliable in a universe that is innately relative and probabilistic as opposed to objective and deterministic? If time, motion, mass, speed, etc can all be considered relative and subjective to the observer.. how could there be one device to accurately measure them all, and itself be the officiator of what is accurate and what is not?

The idea of an ideal anything seems to be a paradox unto itself.
 
  • #102
Sure, an ideal anything is an idealization. There is a lot of very valuable effort which goes into characterizing how a given real measurement device deviates from ideal using only other real measuring devices. This kind of thing is essentially what what the BIPM has to do whenever it decides to change the standard for the second or the meter. Currently our clocks and rods are pretty close to ideal, but our accelerometers and our scales are not nearly so close.
 
  • #103
DaleSpam said:
Sure, an ideal anything is an idealization. There is a lot of very valuable effort which goes into characterizing how a given real measurement device deviates from ideal using only other real measuring devices. This kind of thing is essentially what what the BIPM has to do whenever it desides to change the standard for the second or the meter.

Precisely. Well we do agree after all it seems ;)

As long as we are saying that we create an ideal something for our purposes, though it is not necessarily the de facto rule of the universe.
 
  • #104
Evolver said:
If time, motion, mass, speed, etc can all be considered relative and subjective to the observer.. how could there be one device to accurately measure them all...
The first postulate of SR is that the laws of physics are the same in all inertial reference frames, so experiments that verify SR verify that there is no difference and no reason for a clock to behave differently in different frames.

Or try the corollary: if clocks behaved differently in different inertial reference frames, you could use that difference in functionality to identify the Universal Reference Frame. Failure to find any difference in functionality (ie, with the Michelson Morley Experiment) means a failure of the theory/postulate that different reference frames have different rules and that there is a Universal Reference Frame.

Or a third way: What you are suggesting is testable and is found through experimentation to not be true.
Take your example of the accelerometer. The traveler's will not read zero... if it is an accelerometer based on the Earthbound observer's reference frame. But if the accelerometer were calibrated to read zero as he "accelerated" from the Earthbound observer's perspective, you could say that he was at rest while the Earthbound person and the universe were rapidly accelerating away from him, and that would be the sudden jolt that he felt. And from the "traveler's" perspective the Earthbound person's accelerometer would not be reading zero.
No. If you calibrate the traveling twin's accelerometer to show no acceleration during the acceleration phase of its voyage, then it has to show acceleration during the "coast" phase of its voyage and double acceleration during the "turnaround" phase of its voyage.

All you've done is add a constant to both sides of an equation that cancels out and reduces to the reality that is what has already been said: the acceleration is not relative.

For example:
Both twins standing still out in space (lets avoid gravity): -1g
Accelerating: 0g
Coasting: -1g

Or
Both twins standing still out in space: 0g
Accelerating: 1g
Coasting: 0g

So what hasn't changed is that the difference between the starting frame and accelerating frame is 1g:
0-(-1)=1
or
1-0=1

All you've done is this:
1(-1)-[0(-1)] = 1

So you see, your "calibration" hasn't actually changed the scenario at all. The acceleration is still +1g.
 
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  • #105
russ_watters said:
The first postulate of SR is that the laws of physics are the same in all inertial reference frames, so experiments that verify SR verify that there is no difference and no reason for a clock to behave differently in different frames.

Or try the corollary: if clocks behaved differently in different inertial reference frames, you could use that difference in functionality to identify the Universal Reference Frame. Failure to find any difference in functionality (ie, with the Michelson Morley Experiment) means a failure of the theory/postulate that different reference frames have different rules and that there is a Universal Reference Frame.

Or a third way: What you are suggesting is testable and is found through experimentation to not be true.

Special relativity is formulated so as to not assume that any particular frame of reference is special. Yes they share the same physics, but that does not mean they are perceived the same (besides the speed of light which is the only constant).

For instance the contraction of bodies approaching light speed and the increase of their mass is solely dependent on which observer you ask to find out who's mass increased. For the Earthbound, the traveler contracted and shot away at light speed... for the traveler the Earth contracted and shot away near the speed of light. The observer's intsruments and the Earthbound's would have very different results.

As far as clocks behaving differently in different frames, this can be witnessed in satellites. GPS satellite clocks must be adjusted for because they run at a different rate than Earthbound clocks. They, in effect, experience different time. If this were not done then the GPS data would be compromised. The only reason we prefer one to the other is because we happen to live in one of them. There is no absolute reference frame.

Is that not true?
 
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