Length Contraction causes Time Dilation?

In summary, the person was discussing relativistic effects, and explained that if someone were to travel to Betelgeuse at a sufficient velocity, they would reduce the distance between themselves and Betelgeuse until it was say, 2 light years, which means they would only experience 2 years or so during their journey. However, they pointed out that this would violate the invariance of the spacetime interval, and that length contraction and time dilation are both real physical effects.
  • #36
Max™ said:
Naturally it isn't incorrect to say you measure/observe the universe contracting while you remain unchanged if you assume you're in an inertial frame. How can you make the assumption that you are actually in an inertial frame if you know you accelerated/will need to decelerate at the end of the journey?

An inertial frame is one that is moving at a constant velocity. It does not depend on what happened in the past, nor what is expected to happen in the future.

When you say "the universe contracting" what you are saying that certain objects in the universe are moving with respect to you and the distances between them are Lorentz contracted - according to you. Remember that according to one of those objects, you are the one who is moving and is Lorentz contracted. Similarly, the clocks on those objects appear to be ticking more slowly to you. But to them, your clock is ticking more slowly than theirs. The situation is symmetric, neither one is "right".
 
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  • #37
Passionflower said:
Max™ that statement is absolutely true.

Frankly I am still not convinced you fully accepted the implications of special relativity.

No, the distance being contracted doesn't mean you only have to cross 2 light years which would take just over 2 years at your velocity, either that statement is not true, or I am quite mistaken about special relativity.

If you crossed 640 light years fast enough that it was contracted down to 2 light years in your frame, while avoiding any time dilation strangely, and you then crossed THAT distance fast enough that you took just a little over 2 years to do so, wouldn't you then experience time dilation on THAT duration, and observe quite a bit less than 2 years during your trip?



If the 2 light years in your frame was 640 light years for a signal laser you fired on the same trajectory when you left, then your trip would take more than the 640 years required for a detector at your destination to receive the signal.


Yes, in your frame, you'd only experience/age/observe 2~ years, and claim your laser beam only crossed 2 light years.



If you then turned around and fired a reply laser while going fast enough that you again measure the beam traveling for only 2 years as it crossed 2 light years, you would return 1280+ years after you left, roughly 4 years older.


If the contraction observed from your frame meant you only took 2 years to cross that distance without any effects from time dilation, you'd arrive at Betelgeuse 638~ years before the signal laser, and you'd make it home a thousand years or so before you even left!
 
  • #38
Max™ said:
No, the distance being contracted doesn't mean you only have to cross 2 light years which would take just over 2 years at your velocity, either that statement is not true, or I am quite mistaken about special relativity.

It is true.

Max™ said:
If you crossed 640 light years fast enough that it was contracted down to 2 light years in your frame, while avoiding any time dilation strangely, and you then crossed THAT distance fast enough that you took just a little over 2 years to do so, wouldn't you then experience time dilation on THAT duration, and observe quite a bit less than 2 years during your trip?

Sorry, I don't understand. Anyway, let's not suspend time dilation while keeping Lorentz contraction, it totally confuses everything.

Max™ said:
If the 2 light years in your frame was 640 light years for a signal laser you fired on the same trajectory when you left, then your trip would take more than the 640 years required for a detector at your destination to receive the signal.

Betelguese is 640 light years away according to Earth. It takes 640 years for the light beam to travel there *according to Earth*, not according to the light beam. According to the spaceship, it is 2 light years away, and the light takes 2 years to make the trip.

Max™ said:
If you then turned around and fired a reply laser while going fast enough that you again measure the beam traveling for only 2 years as it crossed 2 light years, you would return 1280+ years after you left, roughly 4 years older.

Right - this is the twin "paradox".

Max™ said:
If the contraction observed from your frame meant you only took 2 years to cross that distance without any effects from time dilation, you'd arrive at Betelgeuse 638~ years before the signal laser, and you'd make it home a thousand years or so before you even left!

This is what the Earth experiences - you and a light beam leave Earth simultaneously, the light beam gets to Betelguese in 640 years, you get there in 640+ years. This is what you experience - you and a light beam leave Earth simultaneously, the light beam gets to Betelguese in 2 years, you get there in 2+ years. If you turn around and head back, along with a light beam, Earth will say that second light beam took 640 years to make the trip, got to Earth 1280+ years after you left. Earth will say you arrived back at Earth 1280++ years after you left. You will say that second light beam took 2 years to reach Earth, and you took 2+ years to get back to Earth, arriving 4++ years after you left. (Here I am using + to mean x+>x and ++ to mean x++ > x+).

The fact that you have only aged 4++ years while those on Earth have aged 1280++ years is called the twin "paradox".
 
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  • #39
In addition:
Max™ said:
[..]
Yes, in your frame, you'd only experience/age/observe 2~ years, and claim your laser beam only crossed 2 light years.
Again: not in "your frame" but in the inertial frame in which you happen to be in rest at that time. That may sound picky but it becomes essential in a continuation of discussion, as now happened:
If you then turned around and fired a reply laser while going fast enough that you again measure the beam traveling for only 2 years as it crossed 2 light years, you would return 1280+ years after you left, roughly 4 years older. [..]
From the experience of the traveler, indeed this will be the case, and he may have difficulty in explaining - based on that experience - why the stay-at home aged so much. You may next want to argue that this proves that the inertial frame of the Earth is something like a True Rest frame - but that's wrong. In relativity all inertial frames are equally valid in the sense that no such frame can be identified from observations.
Here you switched from using one inertial frame to another for one observer. For a reality-like description that is not allowed; in that sense, the class of inertial frames is preferred in special relativity.

For "twin-paradox" scenarios in which one observer switches inertial frames (or in which he uses a non-inertial frame), only* the description of the other observer who does not switch frames provides a consistent and realistic explanation in SR (loosely said: "frame-hopping" leads to inconsistent or unreal descriptions).

Cheers,
Harald

*Einstein tried to get rid of that with GR, but most people nowadays don't appreciate the reality of "induced gravitational fields".
 
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  • #40
Rap said:
It is true.



Sorry, I don't understand. Anyway, let's not suspend time dilation while keeping Lorentz contraction, it totally confuses everything.

This is why that statement wasn't true, the thread was started in response to someone insisting that you don't just suspend time dilation, but that it was caused by the shorter Lortenz contracted distance.



Betelguese is 640 light years away according to Earth. It takes 640 years for the light beam to travel there *according to Earth*, not according to the light beam. According to the spaceship, it is 2 light years away, and the light takes 2 years to make the trip.

A lightlike path connecting Earth and Betelgeuse is 640 light years long and takes 640 years to travel.



There are two events at the start of the thought experiment, we'll just assume the ship was flying past the Earth to confirm that it is not simply a confusion on my part due to an admitted preference for background star reference frames, and to take acceleration out of the equation entirely.


The ship flies past the Earth at the spacetime event: (x+y+z=0, t=2011 CE), and fired a signal laser towards Betelgeuse, the ship synchronized their clocks as they passed by, so they're now tallying up information which they can perform a measurement with. A bored astronomer decides to tally up measurement as well, he records the ship hauling off along the x-axis (for simplicity), with the laser inching further and further ahead of it.


In the ships frame the Earth whizzed past at nearly the speed of light, and continued receding along the x axis, while the laser the ship fired races away at the speed of light towards Betelgeuse.


There is another event of note here, Betelgeuse, located at (x=+640 light years from the Earth/Ship rendezvous point, t=3/30/2011 CE) along a spacelike trajectory oriented along the ships flight path.


In the Earth frame it is just sitting there, 640 years away at the speed of light, picking it's red supergiant nose.

In the ship frame it is hurtling towards the point where the Earth was when the ship passed it at nearly the speed of light.



In 2 years, Earth frame, the astronomer notes that the beam of light has traveled 2 light years, the ship has traveled 1.9999999~ whatever light years, and that Betelgeuse flicked a massive coronal booger roughly in the direction of Rigel... but otherwise did nothing of interest.


At the spacetime event (x=+2 light years from the Earth/Ship rendezvous point, t=3/30/2013 CE), the passenger on the ship checks his instruments and determines that he is at (x=+.011~ or so light years from the E/SrP, t=4/3/2011), a mere 3 days have passed since the Earth flew past him... for some reason, probably a sale at the interstellar mall... and he notes that since his signal laser can't be more than 3 light days ahead of him at this point, he inputs that measurement into his super parallax measuring doohickie and it tells him Betelgeuse is a bit more than 200 times as far away from him as his signal laser, so it must be just under 2 light years away!



Is he correct?

Well yeah, I guess, in a sense, as he has no reason to think he's actually in a frame experiencing major relativistic effects. He did measure the correct distances/duration as far as his frame is concerned.



The question here is, is there any manner in which his completely real and accurate measurements can be reconciled with any frame besides his (besides the arbitrary selection of suitably chosen frames which someone would point out exist if I didn't mention them)?


Is he doomed to watch the squished up universe hurtle past him, Unable to consider that perhaps he was in a boosted frame, and that just maybe his measurements were distorted by it?


Right - this is the twin "paradox".
Uh... no, it's just an aspect of relativity, make no mistake, my issue has nothing to do with a false paradox.


If there was no way for the guy in the ship to determine that he had been in motion, that would give the appearance of a paradox, and this often confuses people upon first hearing it.


If you can't tell by now, my problem is being all too aware of how that "paradox" is resolved. The only way the passenger on the ship can claim the universe is contracted around him is if he can't break the symmetry between his frame and another observers frame.


Setting aside the issue that he would remember accelerating, and putting him in the above described flyby scenario, then yes, he could claim that his frame was inertial and undistorted.

It's a rather scary place, his choice of coordinates, what with stars and planets hurtling past at nearly the speed of light... I mean, yes, we're whirling around along several different axes at anything from a few hundred, to a several thousands, all the way up to a million or so miles an hour depending on which motion you want to consider... but that's pretty far from sitting there with gigantic balls of nuclear fire hurtling towards you at 670 million mph.


This is what the Earth experiences - you and a light beam leave Earth simultaneously, the light beam gets to Betelguese in 640 years, you get there in 640+ years. This is what you experience - you and a light beam leave Earth simultaneously, the light beam gets to Betelguese in 2 years, you get there in 2+ years. If you turn around and head back, along with a light beam, Earth will say that second light beam took 640 years to make the trip, got to Earth 1280+ years after you left. Earth will say you arrived back at Earth 1280++ years after you left. You will say that second light beam took 2 years to reach Earth, and you took 2+ years to get back to Earth, arriving 4++ years after you left. (Here I am using + to mean x+>x and ++ to mean x++ > x+).

The fact that you have only aged 4++ years while those on Earth have aged 1280++ years is called the twin "paradox".

...

/sigh

Again, my issue is in no way related to an inability to understand an example I put forth in an effort to be understood, though the irony is rich enough that it could smother the heart of a massive star and cause it to supernova.



Technically, the twin paradox ONLY arises if you neglect acceleration completely, ANY change in direction breaks the symmetry between the frames, resolving the apparent paradox to be nothing but a quirky result of the way spacetime rotations work.
 
  • #41
Max™ said:
[...]
If there was no way for the guy in the ship to determine that he had been in motion, that would give the appearance of a paradox, and this often confuses people upon first hearing it.
If you can't tell by now, my problem is being all too aware of how that "paradox" is resolved. The only way the passenger on the ship can claim the universe is contracted around him is if he can't break the symmetry between his frame and another observers frame.
That's the heart of relativity - the PoR or symmetry of inertial frames! No need to start talking about twin paradoxes, this is more straightforward. According to relativity there is no way for the guy in the ship to determine that he is "truly" in motion at a certain time, other than a mere assumption about the likely state of "true" motion of the stars. Do you find the Lorentz transformation paradoxical? Did you understand Tiny-tim's explanation in the parallel thread that I linked to (his post #3)?
 
  • #42
Max™ said:
No, the distance being contracted doesn't mean you only have to cross 2 light years which would take just over 2 years at your velocity, either that statement is not true, or I am quite mistaken about special relativity.
Well the statement is true. It takes the traveler a little over 2 years to reach the destination which is 2 lights years away.
 
  • #43
I know all about that, but there is a way for him to determine his frame is not symmetrical with all others, he accelerated.

The "true" motion of the stars doesn't require a mere assumption if you notice they all have a significant vector and velocity relative to you. At rest or not, it pushes the limits of realistic explanations, plus he would notice the blue shift/red shift and aberration of the CMBR... but those are all far above the level of this conversation.

For the record, I first learned about relativity back in the mid 80's, and am well versed in not just the stripped down explanations of the theory as usually provided to laymen, but also the mathematical underpinnings, as well as the rich scientific principles upon which the whole theoretical structure was built almost a hundred years ago.

Now, I was a little datasponge of a 6 year old Aspie, between the bookshelf full of various out of date encyclopedias (I still pull up random factoids from the old white cover 1963 Britannica at the strangest times, my favorites were the A's, M's, P's, and the S's!), and my precious books on Relativity (Black Holes and Warped Spacetime, and Einstein: the Life and Times)... so while it may sound a little improbable for someone to say they've been studying something like Relativity since they were a little kid... it isn't that odd if you've ever met a 6 year old with Asperger's Syndrome. If it wasn't the rock collection, dinosaur trivia, or Legos... I was talking your ear off about how awesome Wheeler and Kerr metrics were.
 
  • #44
Max™ said:
I know all about that, but there is a way for him to determine his frame is not symmetrical with all others, he accelerated.
Ok, how does that invalidate anything?

Max™ said:
The "true" motion of the stars doesn't require a mere assumption if you notice they all have a significant vector and velocity relative to you. At rest or not, it pushes the limits of realistic explanations, plus he would notice the blue shift/red shift and aberration of the CMBR... but those are all far above the level of this conversation.
If your point is absolute motion then it is really back to square one. Motion is relative.

You wrote:
Max™ said:
No, the distance being contracted doesn't mean you only have to cross 2 light years which would take just over 2 years at your velocity, either that statement is not true, or I am quite mistaken about special relativity.

And here is another statement that is true but one that you consider is false:
Max™ said:
"since I can make the distance shorter by going faster, it takes less time to get there",

You keep putting wagers out that some statement is false or you don't understand relativity. Then when people say the statement is actually true, you just come up with other statements and the process repeats.
 
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  • #45
Passionflower said:
Well the statement is true. It takes the traveler a little over 2 years to reach the destination which is 2 lights years away.

Except they don't take 2 years because the distance is contracted, they are in a significantly dilated frame of reference performing distance measurements which are skewed by their reduced motion through time.


You observe a beam of light moving away from you at the speed of light, even if you're going .99999999999999999999~ c, it still races off at full speed, rather than gradually creeping ahead due to you ALMOST being at light speed yourself.


If you're in a Ferrari 458 doing 198 mph side by side with a McLaren MP4-12c doing 200 mph, he's going to ever so slightly nudge out in front and continue crawling further and further ahead.


If you're racing along at almost the speed of light, to an observer as you rush past, you're going to lag bit by bit behind a beam of light. Yet you see the beam zoom off like you were standing still... why?


When you're moving faster through space, you're moving slower through time. What you register as being a second in which the beam of light gains nearly 300,000 kilometers on you is a much longer time for an observer who isn't scooting along quite so quickly as you are.


Note that they don't have to be at rest, if you're doing .99999999999999999999995 c and I'm doing .99995 c, we'll each observe the other appearing to slow down, the clocks we're conveniently holding both seem to tick slower for the other guy, as we've all established repeatedly.


Once we come to a stop though, my clock will have ticked more than yours, I'll have aged a bit quicker than you did, though we both hardly aged compared to someone waiting for us back at Earth.



This is why you can't say "the distances contract, so you take less time to cross them", it's completely backwards. You experience less time because of your velocity, which causes you to claim everything else is contracted.

http://www.phys.unsw.edu.au/einsteinlight/jw/module4_time_dilation.htm#true

So Jasper observes Zoe's clock to tick more slowly by a factor γ, which is always greater than or equal to one. This factor γ occurs regularly in special relativity, so we have plotted it at right. (The dashed line plots 1/γ.) We notice that, unless v is a substantial fraction of c, γ is approximately 1. This of course is why we don't notice time dilation at ordinary speeds. For an airplane traveling near the speed of sound, γ = 1.0000000000005.

Note that 1/γ(v/c) is the equation of a circle, although we have stretched the horizontal axis so that the dashed line looks like an elipse. So γ (the solid line) is conveniently remembered as the reciprocal of a circle.

In the animations, Zoe's car travels at 0.8c, so γ = 1.67, so Jasper measures Zoe's clock to have ticks that are 60% of the time that Zoe measures.

Length contraction
You have probably noticed that, in Jasper's version of events, Zoe's car has shrunk. And vice versa. We haven't proved that yet, but it's logically simple. Suppose that Zoe and Jasper choose to measure lengths in lightyears, lightseconds, lightnanoseconds* etc: ie they measure distance by how long light takes to cover the distance. If they agree on the speed of light, but disagree on measurements of time, they must inevitably disagree on length as well. If you observe someone's clocks run slowly by a factor γ, you will also observe her rulers to be short by a factor of γ: that's the only way that she can measure the speed of light to have the same value you get.

* The lightnanosecond is a convenient unit. c is about 3 x10^8 metres per second, and a nanosecond is 10^-9 seconds, so a lightnanosecond is 0.3 metres. (Americans, who use British imperial units, can therefore remember that the speed of light is about one foot per nanosecond. The rest of us can remember it as 30 centimetres per nanosecond.)

Zoe, who is a graffiti artist in her spare time, will demonstrate this: she decides to tag the two ends of the verandah. (The paint can is green, and it sprays purple paint.) For Jasper, the distance between the tags will be his proper length, ie the length measured in his frame, because they are stationary with respect to him. Zoe can measure the time between the two tags, and thus get her measurement of the length of the verandah.
 
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  • #46
Max™ said:
Except they don't take 2 years because the distance is contracted,
Well then it seems we can agree to disagree. The travelers clock is still going at one second per second. No changes for him at all.

Max™ said:
distance measurements which are skewed by their reduced motion through time.
Their distance measurements are as real as can be.

Max™ said:
you're going .99999999999999999999~ c,
There is no such thing as absolute speed. You can measure the speed of something that has mass only wrt something else that has mass.
 
  • #47
I never said he would notice any changes, his clock ticks off one second every time he expects it should, like... clockwork.


Another observer watching his clock tick from a slower moving frame would see it tick slower (and vice versa), but if the faster moving traveler came to rest beside the slower moving observer it would be obvious that the traveler's clock had ticked less.


I actually was using velocity, and never said anything about absolute speed.

If we were both at rest together in an inertial frame and pulled out two completely identical stopwatches, started them at exactly the same moment, then we both accelerated up to particular fraction of the speed of light, except you got much closer to c than I did, when we came to a stop afterwards your watch would read a shorter duration for your trip than mine would.


Where is the confusion here?
 
  • #48
Max™ said:
A lightlike path connecting Earth and Betelgeuse is 640 light years long and takes 640 years to travel.
This is an example of some sloppy writing which I think is betraying some sloppy thinking that may be the source of your confusion. The quoted sentence is MEANINGLESS as written because the reference frame for the distance and the time measurement are not specified. In order for this statement to be meaningful it would have to be amended as follows:

A lightlike path connecting Earth and Betelgeuse is 640 light years long in the Earth frame and takes 640 years to travel in the Earth frame.

Distance and time are relative quantities, and like all relative quantities, you must identify the reference frame to which they refer. The following statements are also correct for your scenario.

There exists some frame in which a lightlike path connecting Earth and Betelgeuse is 2 light years long and takes 2 years to travel.

In a frame moving 0.999995 c wrt Earth in the direction from Earth to Betelgeuse the distance between Earth and Betelgeuse is 2 light years. In this frame it takes light 1.000002 years to go from Earth to Betelgeuse or 409599 years to go from Betelgeuse to Earth. In this frame it takes 2.00001 years from the time that Earth passes the origin for Betelgeuse to pass the origin.

Notice how relative quantities are always referenced to some specific frame. You make other comments like "they are in a significantly dilated frame of reference" and "he's actually in a frame experiencing major relativistic effects" which lead me to believe that the omission I point out above is not simply a gaffe, but is a basic misunderstanding.
 
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  • #49
See, here's the problem, you're saying the effects are real in that they do happen, I'm saying that as well, but that the cause is due to measurement from a particular frame, not the universe actually smushing up around you.

Time dilation and length contraction are not just optical illusions, but neither do they represent a physical contraction. These effects are the result of a measurement from a given inertial frame that is performed on body moving with respect to that frame. We assume that the measurements always take into account the finite travel time of light. Consider two observers moving relative to one another. You have no difficulty with the idea of their velocities being relative - each thinks the other is "really moving." In SR, time intervals and space intervals are also relative. You don't shrink or see your own clock run slow. The other observer sees your clocks slow and meter sticks contracted from his frame. Similarly you will observe his clocks slow and meters sticks short from your frame. The time dilation and length contraction are inherent properties of the way measurements must be performed in spacetime.

http://www.astro.virginia.edu/~jh8h/Foundations/Foundations_1/quest7.html


I do admit that I'm a bit overly insistent about the broken symmetry, but the length required to treat someone flying from here to another star as an intertial frame leaves a bad taste in my mouth.

I know his frame is accelerated, he knows his frame is accelerated, thinking about the hypothetical inertial frame is one thing, but it is another to claim the particular details of measurement within said hypothetical inertial frame are the cause of the effects you experience in an accelerated frame.

At that point it isn't just a matter of "earth and betelgeuse went flying past me", unless you're pretending GR doesn't exist, and topping it off by pretending that you can't handle acceleration at all in SR (you can, it just doesn't do it very easily).
 
  • #50
Max™ said:
At that point it isn't just a matter of "earth and betelgeuse went flying past me", unless you're pretending GR doesn't exist, and topping it off by pretending that you can't handle acceleration at all in SR (you can, it just doesn't do it very easily).
What has GR to do with this?
 
  • #51
Max™ said:
thinking about the hypothetical inertial frame is one thing
There is nothing hypothetical about the inertial reference frame.

Max™ said:
thinking about the hypothetical inertial frame is one thing, but it is another to claim the particular details of measurement within said hypothetical inertial frame are the cause of the effects you experience in an accelerated frame.
Nobody claimed that. The explanations would be different in a non-inertial frame, but equally valid.
 
  • #52
Passionflower said:
What has GR to do with this?

Well, working with just SR is kinda like me telling you calculate integrals and differentials, but not letting you use the fundamental theorem of calculus to flesh the structure out properly.

SR is great because the mathematical form doesn't require you to keep track of multi-dimensional tensor systems, but it's just not the same as the richer understanding you gain when you include GR into the structure.



As for the inertial frame, if you were flying from here to Betelgeuse you would need to accelerate until the halfway point and then decelerate the rest of the way in order to reach relativistic speeds such as we're discussing, presumably some sort of nuke-pusher drive or maybe an anti-matter pulse engine.


In such a scenario, yes, the inertial frame is a hypothetical, there wouldn't be a period where you would be able to claim you were at rest, much less that your frame hadn't been boosted compared to your origin frame.
 
  • #53
Max™ said:
Well, working with just SR is kinda like me telling you calculate integrals and differentials, but not letting you use the fundamental theorem of calculus to flesh the structure out properly.

SR is great because the mathematical form doesn't require you to keep track of multi-dimensional tensor systems, but it's just not the same as the richer understanding you gain when you include GR into the structure.



As for the inertial frame, if you were flying from here to Betelgeuse you would need to accelerate until the halfway point and then decelerate the rest of the way in order to reach relativistic speeds such as we're discussing, presumably some sort of nuke-pusher drive or maybe an anti-matter pulse engine.


In such a scenario, yes, the inertial frame is a hypothetical, there wouldn't be a period where you would be able to claim you were at rest, much less that your frame hadn't been boosted compared to your origin frame.
Sorry Max I lost you completely here.
 
  • #54
Max™ said:
In such a scenario, yes, the inertial frame is a hypothetical, there wouldn't be a period where you would be able to claim you were at rest, much less that your frame hadn't been boosted compared to your origin frame.
No, the inertial frame is not hypothetical in any way regardless of whether or not the ship is ever at rest in it.

In addition to the sloppy language I pointed out above you seem to have this mistaken notion that there is a requirement for some object to be at rest in order for a reference frame to be valid. That is simply not the case. We need not restrict our analysis to frames where some object is at rest and we need not restrict our analysis to objects which are at rest in our chosen frame.
 
  • #55
Again, why would you think that is what I was saying?

I said an observer who is undergoing constant acceleration can't claim they are in an inertial frame, is this wrong now?
 
  • #56
Max™ said:
I said an observer who is undergoing constant acceleration can't claim they are in an inertial frame, is this wrong now?
Yes, this is wrong as written. It is not possible for something to be "in a frame" or "out of a frame". A frame is a coordinate system, it has infinite spatial extent. An object may be "at rest in a frame" or "moving in a frame", but it exists in every possible frame at all times regardless of its motion.

An observer who is undergoing constant proper acceleration can't claim that they are at rest in an inertial frame. But they may certainly use any arbitrary inertial frame to do physics calculations in anyway.

If you really understand this then why would you repeatedly use the word "hypothetical" to describe the inertial frame where the Earth-Betelgeuse distance is 2 ly?
 
  • #57
I said they can't claim they are in an inertial frame, by which I would have assumed at this point in the discussion it would be implied that I meant "can't claim they are at rest in one", so it is a hypothetical scenario to argue that said observer would be unable to distinguish changes due to a boosted frame of reference from changes due to the universe being smushed up around them.


Yes, from a suitably chosen frame the distance is measured as 2 ly, and if you were at rest in such a frame you would not claim this distortion was due to time dilation.

The observer being described in this scenario can not make such a claim, and accordingly would conclude that the distortion of their measurements was due to time dilation/them experiencing lorentz contraction with their measuring rods.



Similarly, it is hard to ignore the variations in gravity between the Earth and Betelgeuse, though they may be exceptionally slight, nonetheless they break symmetry between all frames, any gravity is an acceleration, even if you were "coasting at rest" (free fall), a sufficiently accurate clock/ruler would display the effects compared to what you would expect when you compared a clock/ruler you know to be in a well at Earth or Betelgeuse to a hypothetical situation where you're coasting between them in perfectly flat spacetime at infinite distance from a gravity well such as those described in SR.

You can define a local frame in GR as an inertial one (assuming you're not spinning, ideally), and if you can get your acceleration components to vanish you could claim your hypothetical ideal observer in that frame is at rest in their locally flat spacetime (i.e. is following a path congruent to a geodesic in that spacetime), and that is about as close as GR gets to the ideal Lorentz frames from SR.
 
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  • #58
Max™ said:
Yes, from a suitably chosen frame the distance is measured as 2 ly, and if you were at rest in such a frame you would not claim this distortion was due to time dilation.

The observer being described in this scenario can not make such a claim, and accordingly would conclude that the distortion of their measurements was due to time dilation/them experiencing lorentz contraction with their measuring rods.
Even if you are not at rest in such a frame you may still use it, and if you used that frame then your time dilation would only be due to your velocity in that frame and other frames (including the Earth frame) would be time dilated.

You seem to think that it is essential for an accelerating observer to refer their observations (including their acceleration) back to the Earth inertial frame and that any other view (either a non-inertial frame or a different inertial frame) represents a "distortion". That misses the point of relativity entirely. Any inertial frame is equally valid and is not considered distorted or invalid in any way. From the 2-ly frame it is the Earth rods and clocks that are so contracted and dilated that they measure 640 ly.

So why insist on referring the ship observations back to the Earth frame rather than some other perfectly valid frame?
 
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  • #59
DaleSpam said:
Even if you are not at rest in such a frame you may still use it, and if you used that frame then your time dilation would only be due to your velocity in that frame and other frames (including the Earth frame) would be time dilated.

Yes, I am aware that this is the case in SR, this is what I was saying, SR is an idealized hypothetical case of GR where acceleration is less important, and where spacetime is a flat Minkowski spacetime.

You seem to think that it is essential for an accelerating observer to refer their observations (including their acceleration) back to the Earth inertial frame and that any other view (either a non-inertial frame or a different inertial frame) represents a "distortion". That misses the point of relativity entirely. Any inertial frame is equally valid and is not considered distorted or invalid in any way. From the 2-ly frame it is the Earth rods and clocks that are so contracted and dilated that they measure 640 ly.
No, I am pointing out that the only important things in General Relativity are paths and their lengths, and as such it is important to treat your choice of frames in a manner which best suits the state in your local region or the local region of another hypothetical observer.

Similarly, an arbitrary choice of Lorentz frames can only be inserted into GR as an approximation of the local spacetime for a particular ideal observer. GR is all about ideal observers, they're everydamnwhere, and it is convenient to assume ideal test particles following true geodesic paths.

In such a situation, those geodesics between two events define minimum possible lengths in time for timelike paths, or space for spacelike paths.


Any inertial frame is equally valid in SR, but not GR, at most they are locally valid.
So why insist on referring the ship observations back to the Earth frame rather than some other perfectly valid frame?

I am actually comparing the observations to an idealized geodesic path between Earth and Betelgeuse, perhaps I shouldn't assume everyone else will take GR into consideration, but there is no reason to NOT use GR to better explain some of the less intuitive aspects of SR, is there?
 
  • #60
Max™ said:
Yes, I am aware that this is the case in SR, this is what I was saying, SR is an idealized hypothetical case of GR where acceleration is less important, and where spacetime is a flat Minkowski spacetime. ...

perhaps I shouldn't assume everyone else will take GR into consideration, but there is no reason to NOT use GR to better explain some of the less intuitive aspects of SR, is there?
Sure, but at these scales both the FLRW metric and the Schwarzschild metric are essentially flat. So GR doesn't add anything significant here.

Max™ said:
No, I am pointing out that the only important things in General Relativity are paths and their lengths, and as such it is important to treat your choice of frames in a manner which best suits the state in your local region or the local region of another hypothetical observer. ...

In such a situation, those geodesics between two events define minimum possible lengths in time for timelike paths, or space for spacelike paths. ...

I am actually comparing the observations to an idealized geodesic path between Earth and Betelgeuse
And in this case the length of the geodesic in question is ~2 ly, not 640 ly. So in terms of paths and lengths the 2 ly frame is the one which best suits the problem, not the Earth frame.
 
  • #61
No, there are proper times and proper lengths, and there are coordinate choices which can lead to different results when those projections are applied to non-boosted frames.

The 2 ly frame is NOT the best solution for describing the problem, it should be nothing more than a sidenote, an "oh, and an observer using his position as the origin of an unaccelerated set of coordinates will project those measurements in such a manner that he will claim the distance is 2 ly", not "this is what happens, there are no invariant properties anywhere, take your beautiful hyperbolic geometry and flush it because we like the description of shrinking rulers and slowing clocks"...

I mean, I suppose your personal taste could lead you to prefer the "contraction/dilation is king" description, but it is not uniquely correct, and it is not the most useful explanation either.

If it had never been put forth in terms of shrinking rulers and slowing clocks we wouldn't have to deal with people getting stuck on silly things like the twin paradox or ladder and barn paradox.


We could have people discussing whether it is better to pronounce "cosh" as (kawsh) or (kose-aytch) instead, ah well.
 
  • #62
Max™ said:
No, there are proper times and proper lengths, and there are coordinate choices which can lead to different results when those projections are applied to non-boosted frames.

The 2 ly frame is NOT the best solution for describing the problem, it should be nothing more than a sidenote, an "oh, and an observer using his position as the origin of an unaccelerated set of coordinates will project those measurements in such a manner that he will claim the distance is 2 ly", not "this is what happens, there are no invariant properties anywhere, take your beautiful hyperbolic geometry and flush it because we like the description of shrinking rulers and slowing clocks"...

I mean, I suppose your personal taste could lead you to prefer the "contraction/dilation is king" description, but it is not uniquely correct, and it is not the most useful explanation either.

If it had never been put forth in terms of shrinking rulers and slowing clocks we wouldn't have to deal with people getting stuck on silly things like the twin paradox or ladder and barn paradox.


We could have people discussing whether it is better to pronounce "cosh" as (kawsh) or (kose-aytch) instead, ah well.
Max, proper times and proper distances are not effected by anyone's choice of reference frame or even if SR is used to analyze the problem. Co-ordinate times and co-ordinated distances are what are effected by the choice of reference frame. It doesn't matter how you analyze the problem, assuming, of course, that you do it in any correct way, the traveler will be able to survive the 2 year trip, his precision clock will advance only 2 years and any correct means that he uses to calculate his distance will determine that he has traveled just under 2 light-years (or whatever your specific scenario is). Again, it doesn't matter which frame of reference you choose to analyze the scenario in. You could even do it with LET believing in an absolute ether rest frame and get the same answers. Do you doubt this?
 
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  • #63
What Max is essentially asserting, I think, is that we cannot just pick EITHER time dilation OR length contraction to describe the journey at relativistic speeds to a far away star, we have to use both. Otherwise there is not point in describing a time dilation AND length contraction. If we say that the velocity is such that the length of the distance between the two bodies in the reference frame of the ship is 2ly, it's not enough to just say "Well, this gives us a shuttle velocity of about 0.9999c, so the trip will take just over 2 years." there is also time dilation in the reference frame of the ship, does it not factor in?
 
  • #64
Max™ said:
The 2 ly frame is NOT the best solution for describing the problem.
I agree, any inertial frame is just as good. But by your reasoning it is the frame where the coordinate interval is closest to the proper interval and it is the frame where the geodesic you were discussing is parallel to the time axis. The Earth frame certainly has no such features, so by your above comments I am surprised that you don't consider it the best solution.
 
  • #65
soothsayer said:
What Max is essentially asserting, I think, is that we cannot just pick EITHER time dilation OR length contraction to describe the journey at relativistic speeds to a far away star, we have to use both. Otherwise there is not point in describing a time dilation AND length contraction. If we say that the velocity is such that the length of the distance between the two bodies in the reference frame of the ship is 2ly, it's not enough to just say "Well, this gives us a shuttle velocity of about 0.9999c, so the trip will take just over 2 years." there is also time dilation in the reference frame of the ship, does it not factor in?
Time dilation and length contraction are reciprocal. The traveler cannot measure or tell if he is experiencing them, he can measure and observe them in the Earth and the star and the space between them. Observers on Earth and the star cannot tell if they are experiencing time dilation and length contraction, they can measure and observe them in the traveler.

Max's problem appears to be that he thinks these measurements are frame dependent, in spite of so many people telling him otherwise, and he probably won't accept it from me either.
 
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  • #66
Note: I am not asserting that time dilation and length contraction both have to be considered, if anything I am asserting that they shouldn't be provided as primary explanations of something easily and correctly represented by hyperbolic trigonometry.

If I were to assert that time dilation and length contraction should be used, though, I would note that any situation where you do has to consider the relativity of simultaneity as well, since dilation/contraction alone are not enough.

ghwellsjr said:
Max, proper times and proper distances are not effected by anyone's choice of reference frame or even if SR is used to analyze the problem. Co-ordinate times and co-ordinated distances are what are effected by the choice of reference frame. It doesn't matter how you analyze the problem, assuming, of course, that you do it in any correct way, the traveler will be able to survive the 2 year trip, his precision clock will advance only 2 years and any correct means that he uses to calculate his distance will determine that he has traveled just over 2 light-years. Again, it doesn't matter which frame of reference you choose to analyze the scenario in. You could even do it with LET believing in an absolute ether rest frame and get the same answers. Do you doubt this?

No, I don't doubt that any method he uses to calculate his distance, if it is based on rulers, or time of flight for a photon, or judging the distance between endpoints based on their appearance, all will give a measurement of 2 light years.

This is because you're assuming the presence of an object sitting between Earth and Betelgeuse which has a length altered by length contraction.


It isn't really wrong, but it's just a description of a kinematic effect, not a dynamic alteration. More accurately you would measure the distance between Event A: the ship passes the Earth, and Event B: the ship passes Betelgeuse.

Alternatively, you would measure the duration/distance between Event A': Earth passes the ship, and Event B': Betelgeuse passes the ship, and apply the appropriate Lorentz transformations to get your result.


Here, found a better wording explaining why we're not getting each other:
According to the “geometric” approach, special
relativity primarily describes the geometry of spacetime. It does not depend on anything
funny happening to the vectors, clocks, rulers, odometers or other objects that inhabit
spacetime. Objects are neither Lorentz contracted nor time dilated; they are completely
unaffected by boosts. The components obtained by projecting a vector onto this-or-that
reference frame are affected, but that is a property of the projective geometry of the situation,
not a property of the vector itself.

http://www.av8n.com/physics/spacetime-trig.pdf


As I mentioned before, the way I learned relativity was the pure geometrical approach Wheeler had been pushing for years, so it is odd to see people arguing for the less useful description/explanation of events.


Oh, btw, I don't know how I missed this earlier, but no, a 2 ly path is NOT a timelike geodesic for this set of events, it is not remotely close, the geodesic between two points is the unaccelerated worldline which maximizes proper time, not one which pushes it close to zero.
 
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  • #67
Max™ said:
Note: I am not asserting that time dilation and length contraction both have to be considered, if anything I am asserting that they shouldn't be provided as primary explanations of something easily and correctly represented by hyperbolic trigonometry.
Are you asserting that Einstein's explanation is not easy or not correct?
Max™ said:
If I were to assert that time dilation and length contraction should be used, though, I would note that any situation where you do has to consider the relativity of simultaneity as well, since dilation/contraction alone are not enough.
Granted, but why after so many posts on your part, you decide now to bring this up for the first time?
Max™ said:
ghwellsjr said:
Max, proper times and proper distances are not effected by anyone's choice of reference frame or even if SR is used to analyze the problem. Co-ordinate times and co-ordinated distances are what are effected by the choice of reference frame. It doesn't matter how you analyze the problem, assuming, of course, that you do it in any correct way, the traveler will be able to survive the 2 year trip, his precision clock will advance only 2 years and any correct means that he uses to calculate his distance will determine that he has traveled just under 2 light-years (or whatever your specific scenario is). Again, it doesn't matter which frame of reference you choose to analyze the scenario in. You could even do it with LET believing in an absolute ether rest frame and get the same answers. Do you doubt this?
No, I don't doubt that any method he uses to calculate his distance, if it is based on rulers, or time of flight for a photon, or judging the distance between endpoints based on their appearance, all will give a measurement of 2 light years.
But is there some other method that would give a different measurement?
Max™ said:
This is because you're assuming the presence of an object sitting between Earth and Betelgeuse which has a length altered by length contraction.


It isn't really wrong, but it's just a description of a kinematic effect, not a dynamic alteration. More accurately you would measure the distance between Event A: the ship passes the Earth, and Event B: the ship passes Betelgeuse.

Alternatively, you would measure the duration/distance between Event A': Earth passes the ship, and Event B': Betelgeuse passes the ship, and apply the appropriate Lorentz transformations to get your result.
Well, as I said, you could even use LET and believe in an absolute ether rest frame (defined by you as one in which both Earth and Betelgeuse are at rest). Way to go! I didn't think anyone would go for that but here we have a true believer.

But even your preferred absolute ether rest frame still affirms that the the traveler is experiencing time dilation and length contraction, correct?

And it also affirms that the traveler will measure that Earth and Betelgeuse are the ones experiencing time dilation and length contraction and not himself, correct?
Max™ said:
Here, found a better wording explaining why we're not getting each other:


http://www.av8n.com/physics/spacetime-trig.pdf


As I mentioned before, the way I learned relativity was the pure geometrical approach Wheeler had been pushing for years, so it is odd to see people arguing for the less useful description/explanation of events.
Is the pure geometric approach of Wheeler the same as the hyperbolic trigonometric explanation mentioned at the beginning of your post?

Does this approach (or any other you want to consider) explain what each observer measures and observes and does it give any different answers than Einstein's method?
Max™ said:
Oh, btw, I don't know how I missed this earlier, but no, a 2 ly path is NOT a timelike geodesic for this set of events, it is not remotely close, the geodesic between two points is the unaccelerated worldline which maximizes proper time, not one which pushes it close to zero.
Was this meant for someone else?
 
  • #68
ghwellsjr said:
Are you asserting that Einstein's explanation is not easy or not correct?

Uh, no, he is the one that said it's just a kinematic effect (i.e. description of motion without delving into the dynamics of the causes), last time I checked.

It definitely isn't as easy as the hyperbolic rotations are. If you understand circular trig (not the hardest subject), you can combine what you know of Euclidean rotations to pick up the geometrical explanation of SR easily.

Granted, but why after so many posts on your part, you decide now to bring this up for the first time?

Well, my main thrust is that presenting length contraction as a cause is incorrect, and that presenting lorentz contraction/dilations as explanations in general is a less elegant/useful formulation.

Pretty sure I questioned why anyone would choose that over a description of hyperbolic angle rotations in the first couple of pages, I do admit that I took for granted that everyone knows the importance of the relativity of simultaneity, but I did bring it up with the description of the scenario indirectly because of how it forces one to specify events.

But is there some other method that would give a different measurement?

Well, yes, if by different measurement you mean "not confusing", then if he treats his measurement of the distance as being passively transformed by the Lorentz effects within his chosen coordinate system, he will be working with the same vector as any other passively transformed set of coordinates would.

If he actively transforms the measurements then you're mapping everything back into your original coordinates in a different way, lending the impression that this is some physical alteration of what you're measuring, which is extremely misleading.

Well, as I said, you could even use LET and believe in an absolute ether rest frame (defined by you as one in which both Earth and Betelgeuse are at rest). Way to go! I didn't think anyone would go for that but here we have a true believer.

What? This has nothing to do with the quote you responded to, I said nothing at all about an absolute ether frame.

I said the mistake in applying a Lorentz contraction to the distance between Earth and Betelgeuse is that you're treating that distance as though it is a physical object, which will give a different result than you would get measuring the distance between two events which are co-local with Earth and Betelgeuse respectively.
But even your preferred absolute ether rest frame still affirms that the the traveler is experiencing time dilation and length contraction, correct?

And it also affirms that the traveler will measure that Earth and Betelgeuse are the ones experiencing time dilation and length contraction and not himself, correct?
Uh... I said nothing at all about a preferred absolute ether rest frame, seriously, where are you getting this?

Nothing in my post is in any way related to such a concept, at all, how did you misread it so completely?


I said using length contraction on the distance as though it is an object is incorrect, that you should apply lorentz transformations to the distance you measure between two events if you're going to use that approach.
Is the pure geometric approach of Wheeler the same as the hyperbolic trigonometric explanation mentioned at the beginning of your post?

Does this approach (or any other you want to consider) explain what each observer measures and observes and does it give any different answers than Einstein's method?

Well, it allows you to construct the Lorentz transformations from the hyperbolic trig functions:

⎡cosh, sinh⎤
⎣sinh, cosh⎦

Which then shows how different observers in different frames, whether they've been boosted or not, would decompose the components of any particular vector into spatial component and temporal component, which then explains the measurements you would make if you were using the contraction/dilation explanation.
Was this meant for someone else?

Yeah, the portion about the geodesic was a response to a comment about "the frame where it's 2 ly is just as good as any other to use as a geodesic", but it doesn't maximize the proper time of the path, so it by default can't be the timelike geodesic for a worldline between those two events.
 
  • #69
A test mass undergoing (non-gravitational) acceleration does not follow a geodesic. So, technically a test mass that takes a path starting at rest on Earth and ending at rest on Betelgeuse is not following a geodesic (i.e., there must be points on its path where (non-gravitational) acceleration occurs). The coordinate independent (space-time rather than just space based) length associated with a path is the proper time that elapses over the path (note that a path need not be a geodesic to have a well-defined length/proper time elapsed). In the case of the rocketship, it is clear that the elapsed proper time between the start and end of its journey is slightly more than two years (assuming the acceleration/decleration is large enough). It is certainly possible to specify coordinate systems in which the coordinate time and (spatial) distances the path covers are much larger than this, but all coordinate systems agree on the proper time elapsed on the path. All of this carries over in the SR approximation since different inertial frames are simply different coordinate systems covering minkowski space. In particular, the proper time elapsed over the path is still coordinate indepenent and therefore frame invarient. There are frames in which the time elapsed and (spatial) distance traveled are longer, but all agree on the proper time elapsed on the path. One's choice of inertial frame (or non-inertial for that matter) in SR does not matter any more than the choice of coordinates matters in any other exercise in geometry (it is only the coordinate invariant properties that matter).

P.S. Sorry for the "wall-of-text".
 
  • #70
Max™ said:
Well, yes, if by different measurement you mean "not confusing", then if he treats his measurement of the distance as being passively transformed by the Lorentz effects within his chosen coordinate system, he will be working with the same vector as any other passively transformed set of coordinates would.

If he actively transforms the measurements then you're mapping everything back into your original coordinates in a different way, lending the impression that this is some physical alteration of what you're measuring, which is extremely misleading.
You were the one who put the word "if" on your statement with regard to an observer making a measurement. I wouldn't put any if's on it. You want to tie measurements in with coordinate systems and transforms. I keep saying that measurements are made without regard to any coordinate system or any transformation (or any theory, for that matter).
Max™ said:
What? This has nothing to do with the quote you responded to, I said nothing at all about an absolute ether frame.

I said the mistake in applying a Lorentz contraction to the distance between Earth and Betelgeuse is that you're treating that distance as though it is a physical object, which will give a different result than you would get measuring the distance between two events which are co-local with Earth and Betelgeuse respectively.

Uh... I said nothing at all about a preferred absolute ether rest frame, seriously, where are you getting this?

Nothing in my post is in any way related to such a concept, at all, how did you misread it so completely?

I said using length contraction on the distance as though it is an object is incorrect, that you should apply lorentz transformations to the distance you measure between two events if you're going to use that approach.
You prefer the Earth-Betelgeuse rest frame over the traveler's rest frame (after he gets inertial). You even admitted as much here:
Max™ said:
There are two events at the start of the thought experiment, we'll just assume the ship was flying past the Earth to confirm that it is not simply a confusion on my part due to an admitted preference for background star reference frames, and to take acceleration out of the equation entirely.
You think it is important or necessary or better or more convenient or less misleading or more elegant or more useful or less confusing for the traveler to establish his rest frames before and after acceleration so that he can transform his measurements done in his traveling rest frame into his pre-acceleration rest frame. And that is the same as believing in an absolute ether rest frame. Now if you would do this in a reciprocal manner and always explain how the Earth should transform all of its measurements into the traveler's rest frame, then I would take back my characterization of your position.
 
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<h2>1. What is length contraction and how does it cause time dilation?</h2><p>Length contraction is a phenomenon in which an object appears shorter in the direction of its motion. This is due to the relativistic effects of time dilation, which causes time to slow down for objects in motion. As an object's velocity increases, its length in the direction of motion decreases, resulting in a shorter perceived length. This is because time and space are interconnected in the theory of relativity.</p><h2>2. How does length contraction and time dilation relate to Einstein's theory of relativity?</h2><p>Einstein's theory of relativity states that the laws of physics are the same for all observers in uniform motion. This means that the effects of length contraction and time dilation are relative and depend on the observer's frame of reference. The theory also explains how these phenomena are a result of the constant speed of light and the interconnection of time and space.</p><h2>3. Is length contraction and time dilation only applicable to objects moving at near-light speeds?</h2><p>Yes, length contraction and time dilation are only significant for objects moving at speeds close to the speed of light. As an object's velocity approaches the speed of light, the effects of length contraction and time dilation become more pronounced. At everyday speeds, these effects are negligible and not noticeable.</p><h2>4. Can length contraction and time dilation be observed in everyday life?</h2><p>No, the effects of length contraction and time dilation are only significant at extremely high speeds, which are not achievable in everyday life. However, these phenomena have been observed and studied in experiments involving subatomic particles and high-speed particles in particle accelerators.</p><h2>5. How does length contraction and time dilation affect our perception of time and space?</h2><p>Length contraction and time dilation challenge our traditional understanding of time and space as absolute and independent quantities. Instead, they show how these concepts are interconnected and relative to the observer's frame of reference. These phenomena also demonstrate the limitations of our perception and the need for a more comprehensive understanding of the universe.</p>

1. What is length contraction and how does it cause time dilation?

Length contraction is a phenomenon in which an object appears shorter in the direction of its motion. This is due to the relativistic effects of time dilation, which causes time to slow down for objects in motion. As an object's velocity increases, its length in the direction of motion decreases, resulting in a shorter perceived length. This is because time and space are interconnected in the theory of relativity.

2. How does length contraction and time dilation relate to Einstein's theory of relativity?

Einstein's theory of relativity states that the laws of physics are the same for all observers in uniform motion. This means that the effects of length contraction and time dilation are relative and depend on the observer's frame of reference. The theory also explains how these phenomena are a result of the constant speed of light and the interconnection of time and space.

3. Is length contraction and time dilation only applicable to objects moving at near-light speeds?

Yes, length contraction and time dilation are only significant for objects moving at speeds close to the speed of light. As an object's velocity approaches the speed of light, the effects of length contraction and time dilation become more pronounced. At everyday speeds, these effects are negligible and not noticeable.

4. Can length contraction and time dilation be observed in everyday life?

No, the effects of length contraction and time dilation are only significant at extremely high speeds, which are not achievable in everyday life. However, these phenomena have been observed and studied in experiments involving subatomic particles and high-speed particles in particle accelerators.

5. How does length contraction and time dilation affect our perception of time and space?

Length contraction and time dilation challenge our traditional understanding of time and space as absolute and independent quantities. Instead, they show how these concepts are interconnected and relative to the observer's frame of reference. These phenomena also demonstrate the limitations of our perception and the need for a more comprehensive understanding of the universe.

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