The case for True Length = Rest Length

In summary, the conversation discusses Lorentzian length contraction and time dilation in the context of Special Relativity. The difference between spatial and temporal components of travel is emphasized and demonstrated through the example of a car moving at different speeds. The concept of Lorentzian length contraction is explained using the analogy of a Rubik's Cube, and it is argued that it is merely an illusion. The conversation also touches upon the relativity of simultaneity and the fact that there is no absolute truth about velocity. The limitations of the diagrams used in the conversation are also pointed out.
  • #36
JesseM said:
If so can you explain what you mean by "direction of an object's constant spacetime velocity as it relates to it's temporal and spatial components" in mathematical terms like this? Are you imagining a sort of graph where we plot (which is just the magnitude of the velocity vector, i.e. speed) on one axis and on the other, such that the length of the vector for any object always adds up to 1? And is the "direction" you're talking about in this abstract space of speed vs. time dilation, rather than direction in ordinary spacetime? If so how does this have anything to do with length contraction?
What I'm doing is trivially assigning the physical manifestation of the quantity that is invariant under Lorentz tranforms in SR to be considered a "spacetime velocity". This quantity, by definition, will remain constant for all frames. I've "lumped together" the spatial vector components for simplicity because when discussing SR length contraction and time dilation we don't frankly care which way the object is moving, only that it's moving spatially.
JesseM said:
My critique is that I see no connection whatsoever between visual foreshortening and length contraction, you need to actually explain what the details of the analogy are.
I guess I'll start over...
The diagram below is completely different by design - I don't want people trying to analyze it with traditional Minkowski spacetime diagram prejudices which I think may have been part of my problem. The Y direction represents an object's speed through space (specifically, what we traditionally think of when we say "speed"); the -X direction represents an object's "speed" through time; the needle has a fixed length of C, representing the Lorentz-invariant quantity in SR that we are physically representing here; finally, the speedometer's numbers very roughly signify the object's spacetime velocity's percentage of "rotation" through the space and time diagram. (Ideally, 100% would be directly at the top, coinciding with an object moving through space at C, but it's late and I'm tired!)
5488252894_a08a5f08f3.jpg

The above diagram shows an object at rest. It's Y component is zero, signifying zero spatial-velocity. It's -X component is C, signifying a temporal-velocity of C. What does it mean to be moving at 1 second per second? It means that we observe that the object is experiencing no time dilation.

5487656823_d9185bf1b8.jpg

Now, this object is moving such that it's spatial and temporal component vectors are equal in magnitude. As you can see, its Y component would be .707, as would its -X component. This coincides precisely with what SR calculates as the time dilation factor of an object moving in such a manner.

Presuming the above explanations make sense, the parallax-induced (aka "foreshortening") length contraction analogy is simple (it may help to consider the speedometer to be sitting flat on a table for this): Physically replace the needle with the Rubik's Cube face, as the "true" face width (let's call it W) is invariant to rotation; next, consider the -X direction to be the "apparent face width" and the Y direction to be depth; lastly, consider the speedometer reading to be the percentage of rotation of the Rubik's Cube face from being sitting squarely in front of us through being completely inline with our vision such that it's apparent width is zero.
5487770559_a32a10cfd2.jpg

Above is a Rubik's Cube with blue face width of W.

5488366238_eedb8a90c5.jpg

Above is the same Rubik's Cube, rotated 50% (or 45 degrees) through the depth dimension Y. It's "apparent", parallax-induced, foreshortened blue-face width is now .707W, which means that the foreshortening factor is exactly what we calculated the Lorentzian time-dilation and length-contraction factor to be above.

The point is that if we consider foreshortening to be illusory, and I presume we all do, then I maintain that Lorentzian length contraction should also be considered illusory.

...Whew! Does this help?
 
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  • #37
Mentz114 said:
I'm disappointed by your reply, where you've thrown questions rather than reply to what I explained very simply.
Instead of expressing your disappointment perhaps you should actually answer the questions. "Objective reality" is not a term I have ever used and I don't know how you are using it. I am particularly interested in your response to this question:

Is your idea of "objective reality" fundamentally incompatible with relative quantities?
 
  • #38
DaleSpam said:
Instead of expressing your disappointment perhaps you should actually answer the questions. "Objective reality" is not a term I have ever used and I don't know how you are using it. I am particularly interested in your response to this question:

Is your idea of "objective reality" fundamentally incompatible with relative quantities?

For the purposes of this discussion, all I ask is this:

If an object is transported from one laboratory to another that is moving relative to the first laboratory, then if its length is measured in that lab, the outcome will be the same as the identical procedure that was carried out earlier in the first lab. So there is some property of the object that was unaffected by being moved between the labs. Sort of like "the laws of physics are the same in all inertial frames".

Allowed this premise, I assert that relativistic effects cause miscalibrated measurements to give wrong answers. However if the instruments are made so they can take into account these effects, then all inertial observers will actually be measuring the length, and agreeing. Using miscalibrated measurement procedures, one is not measuring anything.

A question for you, if there is no objective reality, what exactly is the nature of thing you call length, and is there any point in measuring it ?

I have to leave now, but I'll check in again in about eight hours.
 
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  • #39
Mentz114 said:
For the purposes of this discussion, all I ask is this:

If an object is transported from one laboratory to another that is moving relative to the first laboratory, then if its length is measured in that lab, the outcome will be the same as the identical procedure that was carried out earlier in the first lab. So there is some property of the object that was unaffected by being moved between the labs.

Allowed this premise, I assert that relativistic effects cause miscalibrated measurements to give wrong answers. However if the instruments are made so they can take into account these effects, then all inertial observers will actually be measuring the length, and agreeing. Using miscalibrated measurement procedures, one is not measuring anything.

A question for you, if there is no objective reality, what exactly is the nature of thing you call length, and is there any point in measuring it ?

I have to leave now, but I'll check in again in about eight hours.

So, to be clear, you would call the following a mis-calibrated mearurement:

A rocket with rest length of 100 meters is moving by at relativistic speed. I have a pair of super fast barriers I can raise and lower simultaneously (as I see it). I can momentarily contain the rest length 100 meter rocket between my barriers set 10 meters apart. My conclusion that the length is less than 10 meters is mis-calibrated, and inferior in some way to the rocket's own perception that what happened is that a barrier went up and down in front of the rocket, then both barriers moved, then the other barrier went up and down behind the rocket.
 
  • #40
PAllen said:
A rocket with rest length of 100 meters is moving by at relativistic speed. I have a pair of super fast barriers I can raise and lower simultaneously (as I see it). I can momentarily contain the rest length 100 meter rocket between my barriers set 10 meters apart. My conclusion that the length is less than 10 meters is mis-calibrated, and inferior in some way to the rocket's own perception that what happened is that a barrier went up and down in front of the rocket, then both barriers moved, then the other barrier went up and down behind the rocket.
First of all, I'd like to announce that I realize this issue is 100% subjective and ultimately "undecidable". I just started this thread to issue my take on it.

The scenario above, though, has an analogy in my Rubik's Cube mentioned a couple of posts back...relative motion is analogous to a differing amount of physical rotation, so your 100m rocket would indeed fit between two barriers set 10m apart if it was twisted to the side. My position is that to say that the twisted rocket is now "truly" less than 10m long is a fallacy.
 
  • #41
rjbeery said:
What I'm doing is trivially assigning the physical manifestation of the quantity that is invariant under Lorentz tranforms in SR to be considered a "spacetime velocity". This quantity, by definition, will remain constant for all frames. I've "lumped together" the spatial vector components for simplicity because when discussing SR length contraction and time dilation we don't frankly care which way the object is moving, only that it's moving spatially.
Yes, I understood that you were just talking about the total magnitude of the velocity vector rather than its individual components, that's why I said:
Are you imagining a sort of graph where we plot [tex]\sqrt{(d\vec{x}/dt)^2}[/tex] (which is just the magnitude of the velocity vector, i.e. speed) on one axis and [tex]d\tau/dt[/tex] on the other, such that the length of the vector for any object always adds up to 1?
If you plot speed vs. [tex]d\tau/dt[/tex] (which is just 1/gamma) you get the graph that ghwellsjr posted in this thread:

attachment.php?attachmentid=32565&thumb=1&d=1298690332.png


Just a segment of a circle, with each point having the same distance from the origin. That's what you're representing in your speedometer drawings too. But the argument about what this implies about length contraction is still unclear to me. You say:
rjbeery said:
Presuming the above explanations make sense, the parallax-induced (aka "foreshortening") length contraction analogy is simple (it may help to consider the speedometer to be sitting flat on a table for this): Physically replace the needle with the Rubik's Cube face, as the "true" face width (let's call it W) is invariant to rotation; next, consider the -X direction to be the "apparent face width" and the Y direction to be depth; lastly, consider the speedometer reading to be the percentage of rotation of the Rubik's Cube face from being sitting squarely in front of us through being completely inline with our vision such that it's apparent width is zero.
5487770559_a32a10cfd2.jpg

Above is a Rubik's Cube with blue face width of W.

5488366238_eedb8a90c5.jpg

Above is the same Rubik's Cube, rotated 50% (or 45 degrees) through the depth dimension Y. It's "apparent", parallax-induced, foreshortened blue-face width is now .707W, which means that the foreshortening factor is exactly what we calculated the Lorentzian time-dilation and length-contraction factor to be above.

The point is that if we consider foreshortening to be illusory, and I presume we all do, then I maintain that Lorentzian length contraction should also be considered illusory.

...Whew! Does this help?
First of all, it seems a little confusing to have the cube rotate in the "depth" direction (into the computer monitor) when the vector representing "speed through spacetime" (the needle on the speedometer) never rotates in that direction (always stays in the plane of the monitor). I suppose you could say that we were just changing our perspective on the speedometer so we were looking up at the needle from "below", sitting far down along the y-axis (our line of sight being in the same plane as the speedometer, as if we were flatlanders), in this case as the needle rotated, the needle itself would appear visually foreshortened in exactly the same way as the side of the Rubik's cube, and if we were a far distance away so that our lines of sight to each end were essentially parallel, we would see it foreshortened by exactly the same amount as needle's length component on the x-axis. Since the length contraction factor and [tex]d\tau/dt[/tex] are both equal to 1/gamma, this foreshortening would be proportional to the length contraction factor. In fact we might improve the analogy if instead of having the axes be speed vs. [tex]d\tau/dt[/tex], we had the y-axis be (speed*rest length/c) and the x-axis be moving length...in that case the length of the "needle" could always be equal to the rest length, while the component of the needle that lies along the x-axis would be the moving length, and that would be the foreshortened apparent visual length seen by an observer a great distance away along the y-axis.

But it seems to me this is just a happenstance fact about mathematical similarities between length contraction and rotated needles seen at a great distance, it doesn't make sense to me to say that because the numbers work out, that means length contraction "really is" just a consequence of "viewing" some vector in an abstract space of (speed*rest length/c) vs. (moving length) at an angle--after all, we measure length in real space and time, not in this abstract space! Also, wouldn't it be just as much a consequence of your argument that you should say the "true" value of the rate a clock ticks is always 1 second/second, and that any apparent change is an "illusion" caused by the foreshortening of a needle in an abstract space of (speed/c) vs. (rate of ticking in frame where clock is moving)?
 
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  • #42
JesseM said:
First of all, it seems a little confusing to have the cube rotate in the "depth" direction (into the computer monitor) when the vector representing "speed through spacetime" (the needle on the speedometer) never rotates in that direction (always stays in the plane of the monitor).
Agreed! The perspective with the cube and the speedometer isn't perfect, which is why I wrote
RJBeery said:
Presuming the above explanations make sense, the parallax-induced (aka "foreshortening") length contraction analogy is simple (it may help to consider the speedometer to be sitting flat on a table for this)
I'm actually a bit frustrated because I stayed up quite late crafting my speedometer post, which is why I had to cut some corners, but apparently I never hit "Submit" in my sleepy state so I had a late night for naught!
Anyway, I'm asserting a correspondence between Lorentz transforms and foreshortening. When you view SR in the manner that I described, both phenomena involve rotating an invariant between 2 perpendicular dimensions. In the former case we are claiming that something is "actually changing" while in the latter case we all acknowledge that it's simply an illusion. All are welcome to continue to hold their own views, obviously, but I find the analogy to be convincing.

Also, consider Wiki's explanation of the bar-and-ring paradox:
Wiki on bar and ring paradox said:
In mathematical terms, a Lorentz transformation can be separated into the product of a spatial rotation and a "proper" Lorentz transformation which involves no spatial rotation. The mathematical resolution of the bar and ring paradox is based on the fact that the product of two proper Lorentz transformations may produce a Lorentz transformation which is not proper, but rather includes a spatial rotation component.
In other words, the bar and ring problem is resolved by one party disagreeing with the other on the amount of relative rotation between the two objects! If a simple rotation can explain how we fit a 2 meter pole through a 1 meter ring in that scenario, doesn't it support the analogy between Lorentz length contraction and a physical rotation?
 
  • #43
Mentz114 said:
If an object is transported from one laboratory to another that is moving relative to the first laboratory, then if its length is measured in that lab, the outcome will be the same as the identical procedure that was carried out earlier in the first lab.
No, it won't, unless the object is Born-rigidly accelerated such that the object's velocity relative to the second lab is the same as the velocity relative to the first lab.

I am sorry Mentz114, but your stance here is completely contrary to SR. In SR length is a relative quantity, meaning that it depends on the frame of reference. It is not a property of the object itself.

Mentz114 said:
A question for you, if there is no objective reality, what exactly is the nature of thing you call length, and is there any point in measuring it ?
I have told you 3 times now that I don't know what you mean by "objective reality". You should stop being evasive about the meaning of your terms. In that vein, I will gladly define "the thing I call length":

The length of an object is the distance between the two ends of an object at the same time in some specified reference frame.

I would now appreciate an answer to the question which you have avoided twice now: Is your idea of "objective reality" fundamentally incompatible with relative quantities?
 
  • #44
rjbeery said:
If a simple rotation can explain how we fit a 2 meter pole through a 1 meter ring in that scenario, doesn't it support the analogy between Lorentz length contraction and a physical rotation?
Yes. That is why it was discussed at length in the other threads.
 
  • #45
DaleSpam said:
The length of an object is the distance between the two ends of an object at the same time in some specified reference frame.
DaleSpam, presuming that you consider foreshortened lengths to be illusory, your definition of "distance" probably involves correcting for foreshortening effects, correct? Why is it that you would correct for foreshortening effects but not for relativistic effects if the math and procedure is similar?
 
  • #46
rjbeery said:
DaleSpam, presuming that you consider foreshortened lengths to be illusory, your definition of "distance" probably involves correcting for foreshortening effects, correct? Why is it that you would correct for foreshortening effects but not for relativistic effects if the math and procedure is similar?
No, I don't consider projected lengths (what you call "foreshortened lengths") to be illusory. They are simply projections from a higher dimensional space onto a lower dimensional space.

e.g. I do not consider the length of a shadow to be an illusion; the shadow actually has some length. Also, I would not confuse the length of a shadow with some property of the object casting the shadow, and I would recognize that if the shadow were cast from a different light source that the result could be different without there being any paradox or contradiction.
 
  • #47
I think there is an issue here with rigid bodies and how they are, in fact, not allowed in special relativity. Special relativity is violated by rigid bodies since, they transmit cause and effect at infinite speed between 2 end points. We should only consider point particles in special relativity. In this sense, the fact that the space "contracts" between 2 points when you are moving between those 2 points can easily be seen in the following experiment (taking time-dilation for granted):

Suppose particle A and particle B is 1 light-second apart in my (at rest w.r.t. A and B) frame of reference. There is a spaceship, traveling at velocity = .5c from particle A to particle B. At t=0 me, particle A, and the spaceship all coincide in position and the spaceship and me synchronize our watches.

From my POV, the space-ship is traveling at .5c from A to B, from the space-ship's POV, point B is moving towards him at .5c and point A is moving away from him at .5c. So, for me the spaceship will get from A to B in 2 seconds. For the space-ship though, B will arrive at where he is in (I am unprimed, space-ship is primed)

[tex]t'=\frac{t}{\gamma} = 1.732s[/tex] (The space-ship is the one measuring proper time)

Therefore he will say that the distance that point B has traveled from the time that A coincided with him to be:

d'=.5c*t'=.866 light-seconds.

Therefore, the space-ship must have measured a contracted distance between A and B than I did because his time has been dilated and I must measure the same velocity that the spaceship has that the spaceship measure me to have (otherwise, we would have some paradox like he is traveling at .5c away from me, but in his perspective, I am traveling at v not equal to .5c away from him).

If we then ask "what is the ACTUAL or TRUE distance between A or B", then there is no good answer because if you take the length I measure to be some "true distance", then the space-ship which is moving relative to me can never MEASURE this "true" distance (the people can write some equations and try to figure it out, I suppose).

Since there are no rigid bodies in SR, I cannot somehow put a perfectly rigid rod between A and B, and allow the space-ship to measure the distance I would measure by transporting that rod to the space-ship.

Whether you really want to call my measurement the "true" distance and the space-ship's measurement somehow an "untrue" distance, I think is more up to philosophy than actual physics.
 
  • #48
DaleSpam said:
I do not consider the length of a shadow to be an illusion; the shadow actually has some length. Also, I would not confuse the length of a shadow with some property of the object casting the shadow, and I would recognize that if the shadow were cast from a different light source that the result could be different without there being any paradox or contradiction.
Ahh, exactly! The shadow has some length, but when you say
DaleSpam said:
The length of an object is the distance between the two ends of an object at the same time in some specified reference frame.
...you are referring to the distance between the ends of the projected object, NOT the shadow itself. When you observe a foreshortened object you do 1 of 3 things:

1) Turn the foreshortened object squarely with yourself and measure it.
2) Turn your measuring device to match the angle of the foreshortened dimension you're trying to measure.
3) Measure the foreshortened length (or, if you prefer, the length of the shadow), and mathematically calculate what the "true length" of the object is.

Each one of these actions has an SR analogue. When you observe a Lorentz-contracted object you (could) do 1 of 3 things:

1) Bring the object under consideration into your rest frame.
2) Send your measuring device into the moving frame of the object.
3) Measure it's contracted length and correct your answer taking into consideration the Lorentz transform determined by your relative velocity.

In my opinion it's the SAME THING. By claiming that a shadow has a definite length which is separate from the object's "true length" you are merely reasserting my claim that a length-contracted object has a definite length which is separate from that object's "true length".
 
  • #49
Wavematter said:
Whether you really want to call my measurement the "true" distance and the space-ship's measurement somehow an "untrue" distance, I think is more up to philosophy than actual physics.
Yes, in the end this is undeniable of course. However, would you also argue that the foreshortened width of the Rubik's Cube a few posts back is just as "true" a width as if we were to measure the width squarely?
 
  • #50
rjbeery said:
...you are referring to the distance between the ends of the projected object, NOT the shadow itself.
The measurement of length is a projection of a 4D object onto a 3D space called a hyperplane of simultaneity. In that sense, it is in fact a "shadow".

rjbeery said:
When you observe a foreshortened object you do 1 of 3 things:

1) Turn the foreshortened object squarely with yourself and measure it.
2) Turn your measuring device to match the angle of the foreshortened dimension you're trying to measure.
3) Measure the foreshortened length (or, if you prefer, the length of the shadow), and mathematically calculate what the "true length" of the object is.
Or 4) measure the length of the projection and recognize that it is a projection.

The point is that the distance between two ends of an object at some instant in a given reference frame is some number. That number is named "length". You may not like the fact that that number is called "length" but your opinion is not relevant and does not change the facts.
 
  • #51
rjbeery said:
Yes, in the end this is undeniable of course. However, would you also argue that the foreshortened width of the Rubik's Cube a few posts back is just as "true" a width as if we were to measure the width squarely?

I would hope that you would read more of my post than just the last statement.

Since option 1 and 2 that you posted, are not possible, and 3 is just manipulating some formulas, then I would say that there is no better reason to call the distance I measure to be "true" than to call, say, the rest-energy of a particle as it's "true" energy.
 
  • #52
DaleSpam said:
The measurement of length is a projection of a 4D object onto a 3D space called a hyperplane of simultaneity. In that sense, it is in fact a "shadow".
I see, so you're saying that the foreshortened width of the Rubik's Cube as it's projected from 3D onto our 2D perspective devoid of depth IS ACTUALLY the width? You've defined length in these terms, I'm just applying your definition.
DaleSpam said:
your opinion is not relevant and does not change the facts.
I'm sorry you feel this way; I feel my logic is sound, but if you think my opinion is irrelevant why are we having this discussion? For the sake of others?
 
  • #53
rjbeery said:
I'm sorry you feel this way
It is not a feeling. The process I described has been the accepted definition of "length" since Einstein's 1905 OEMB paper.
 
  • #54
Matterwave said:
Since option 1 and 2 that you posted, are not possible, and 3 is just manipulating some formulas, then I would say that there is no better reason to call the distance I measure to be "true" than to call, say, the rest-energy of a particle as it's "true" energy
Yes, I read the entire post. I'm not saying that length contraction has no consequences. That being said, I think there's a very valid reason to consider the rest-energy of a particle as its "true" energy...and that is because it's the only energy that is intrinsic to it. "Where" exactly does the additional energy of an object with relativistic velocity reside? Certainly not in the object itself!
 
  • #55
DaleSpam said:
The process I described has been the accepted definition of "length" since Einstein's 1905 OEMB paper.
...and I'm pointing out the following shortcoming with that definition which you did not address.
RJBeery said:
I see, so you're saying that the foreshortened width of the Rubik's Cube as it's projected from 3D onto our 2D perspective devoid of depth IS ACTUALLY the width? You've defined length in these terms, I'm just applying your definition.
 
  • #56
rjbeery said:
Anyway, I'm asserting a correspondence between Lorentz transforms and foreshortening.
But it's purely a mathematical analogy involving abstract vectors in abstract an abstract space of speed vs. time dilation (or length contraction). Would you agree that in the actual 3 dimensions of space plus one of time, there is no sense in which length contraction follows from foreshortening, i.e. the angle between lines-of-sight to either end shrinking because we are viewing the object at an angle?

Consider the analogy I earlier mentioned as being more similar to length contraction, the one of considering the "width of a horizontal 2D cross-section" of a 3D object like a cylinder, which of course depends on the amount that the 2D plane you're defining as "horizontal" is inclined relative to a plane orthogonal to the central axis of the cylinder (call that the "orthogonal plane"). Now suppose we instead consider the inverse, or "1/width of a horizontal 2D cross-section". If theta is the angle between the plane we define as horizontal and the "orthogonal plane", then it works out that "1/width of a horizontal 2D cross-section" = cos(theta)*"1/width of a 2D cross-section taken in the orthogonal plane". So we could draw a speedomenter diagram where the x-axis represented "1/width of a horizontal 2D cross-section", and the angle that the speedometer needle makes with the x-axis is the same as the angle between the plane you define as "horizontal" and the orthogonal plane. In that case, if the needle has a constant length "1/width of a 2D cross-section taken in the orthogonal plane", then as it rotates through different angles, the length of its "shadow" on the x-axis (or the foreshortened visual length seen by someone at a great distance along the y-axis) would correctly represent "1/width of a horizontal 2D cross-section" for the "horizontal" plane at that angle relative to the orthogonal plane. Do you think this representation of "1/width of a horizontal 2D cross-section" as the shadow of a needle in an abstract space somehow proves that the "true" value of "1/width of a horizontal 2D cross-section" is the value it takes when we define the "horizontal" plane to be the same as the orthogonal plane, the plane at a right angle to the central axis of the cylinder? So somehow we are "wrong" if we define "horizontal" in a way where the central axis of the cylinder is not "vertical"?

(if you have trouble following this, it may help to replace the cylinder with a 2D strip and the 2D planes with 1D lines)
rjbeery said:
Also, consider Wiki's explanation of the bar-and-ring paradox:
Wiki on bar and ring paradox said:
In mathematical terms, a Lorentz transformation can be separated into the product of a spatial rotation and a "proper" Lorentz transformation which involves no spatial rotation. The mathematical resolution of the bar and ring paradox is based on the fact that the product of two proper Lorentz transformations may produce a Lorentz transformation which is not proper, but rather includes a spatial rotation component.
In other words, the bar and ring problem is resolved by one party disagreeing with the other on the amount of relative rotation between the two objects! If a simple rotation can explain how we fit a 2 meter pole through a 1 meter ring in that scenario, doesn't it support the analogy between Lorentz length contraction and a physical rotation?
No, because in this case we are dealing with a "real" rotation in ordinary 3D space, not in some abstract phase space we've cooked up.
 
  • #57
rjbeery said:
I see, so you're saying that the foreshortened width of the Rubik's Cube as it's projected from 3D onto our 2D perspective devoid of depth IS ACTUALLY the width? You've defined length in these terms, I'm just applying your definition.
No you are not applying the definition. You are simply deliberately confusing an analogy with a definition.

I would say: "the foreshortened width of the Rubik's Cube as it's projected from 3D onto our 2D perspective devoid of depth IS ANALOGOUS to the width"
 
  • #58
DaleSpam said:
The measurement of length is a projection of a 4D object onto a 3D space called a hyperplane of simultaneity.
I have to correct myself. The measurement of length is an intersection of a 4D object with a 3D space called a hyperplane of simultaneity. Intersection and projection are related, but not the same.

In any case, length is a well-defined term, and it has the property that it is frame variant. End of story.
 
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  • #59
rjbeery said:
Yes, I read the entire post. I'm not saying that length contraction has no consequences. That being said, I think there's a very valid reason to consider the rest-energy of a particle as its "true" energy...and that is because it's the only energy that is intrinsic to it. "Where" exactly does the additional energy of an object with relativistic velocity reside? Certainly not in the object itself!

This is not a problem with relativity, even under Galilean transforms, the energy is frame-dependent. So, are you really saying that the "true kinetic energy" of a particle is always 0?
 
  • #60
DaleSpam said:
In any case, length is a well-defined term, and it has the property that it is frame variant. End of story.
Very intellectually brave of you.:wink: Anyway, I've never technically mentioned redefining "length", I've just been laying out out the reasons I personally consider an object's proper length to be its "true length". In almost all human experience the colloquial "length" and what I'm calling the "true length" are going to be the same thing. In any event, why do you continue to try persuading me? I thought my opinion was irrelevant?
 
  • #61
rjbeery said:
In almost all human experience the colloquial "length" and what I'm calling the "true length" are going to be the same thing.
So what? Relativity is designed to also work in situations outside of that small realm of experience.

rjbeery said:
I've just been laying out out the reasons I personally consider an object's proper length to be its "true length".
Out of curiosity, why do you feel the need to change the term from "rest length" to "true length"? After all, your "true length" is exactly the same as the standard "rest length", so why do you feel the need to invent a new term when a standard one already exists.
 
  • #62
Matterwave said:
So, are you really saying that the "true kinetic energy" of a particle is always 0?
Yes. A particle cannot have "true kinetic energy". Kinetic energy exists in the INFORMATION between two objects as a POTENTIAL to do work, not in either one of them individually. If you don't believe me, throw a baseball and calculate what its apparent kinetic energy is from various moving points around the Universe.
 
  • #63
rjbeery said:
Kinetic energy exists in the INFORMATION between two objects as a POTENTIAL to do work, not in either one of them individually.
Do you think there is a "true" kinetic energy "between two objects" then? The total kinetic energy of the pair depends what frame you use too...
 
  • #64
rjbeery said:
Yes. A particle cannot have "true kinetic energy". Kinetic energy exists in the INFORMATION between two objects as a POTENTIAL to do work, not in either one of them individually. If you don't believe me, throw a baseball and calculate what its apparent kinetic energy is from various moving points around the Universe.

Uh...even without a potential, objects can have kinetic energy, and the difference in kinetic energy is especially meaningful (even if the absolute value is not).

For example, a particle moving at .5c in one reference frame really should be assigned a higher kinetic energy as a particle moving at .1c in that same reference frame...a lot of physics would be thrown out the window if you just assigned them both 0 kinetic energy.
 
  • #65
The 'rest momentum' of all particles is zero. So all momentum is an illusion.







I hope ;) is obvious.
 
  • #66
PAllen said:
So, to be clear, you would call the following a mis-calibrated mearurement:

A rocket with rest length of 100 meters is moving by at relativistic speed. I have a pair of super fast barriers I can raise and lower simultaneously (as I see it). I can momentarily contain the rest length 100 meter rocket between my barriers set 10 meters apart. My conclusion that the length is less than 10 meters is mis-calibrated, and inferior in some way to the rocket's own perception that what happened is that a barrier went up and down in front of the rocket, then both barriers moved, then the other barrier went up and down behind the rocket.

PAllen,

I really love the way you described the old "pole in the barn" example.
 
  • #67
JesseM said:
Do you think there is a "true" kinetic energy "between two objects" then? The total kinetic energy of the pair depends what frame you use too...
Well frankly I think anyone here would have a hard time strictly defining energy of any sort without a bit of hand-waving. "The ability to do work" is very common but...you seem to be suggesting that the ability of two objects to do work depends upon who is observing them. This doesn't seem right to me; does it to you?

If kinetic energy "actually existed" then I could create something approaching an infinite amount of energy by simply jumping in the air...just THINK of all that energy created between me and the infinitude of masses moving at varying relative velocities all over the Universe! :tongue:
 
  • #68
So, your argument is starting to sound more and more like you're Zeno (a stoic who believe motion was illusion)! According to the same reasoning as your argument then, "true velocity" is 0 always!
 
  • #69
Mentz114 said:
ghwellsjr said:
what they fail to realize is that the rest length is identically an illusion (if it is an illusion) because the ruler that is used to measure a rod at rest is also contracted to the same degree as the rod that is being measured.
That is sophistry and has no content.

Why do you think that one object ( something with a single manifestation) can have more than one length ?
Where did I ever say or imply that I think one object can have more than one length?

Greg and rjbeery are the ones, and now maybe you too, that believe that one object can have more than one length. I have said that you need to pick one inertial reference frame and then define, observe, analyze or do whatever you want for everything (all objects and all observers) according to that one frame. The lengths of all objects will have unique values assigned to them according to your arbitrarily selected reference frame.

Greg and rjbeery, and now maybe you too, want to use two different frames at the same time, one for each observer/object. They want to call the length of the first object the true length in one frame while the length of the second object is illusory and at the same time they want to call the length of the second object the true length in a second frame while the length of the first object is illusory. So they, and now maybe you too, want to have multiple lengths for each object, one they call true and the other one they call illusory.

This is not the way Special Relativity works.
 
  • #70
rjbeery said:
Well frankly I think anyone here would have a hard time strictly defining energy of any sort without a bit of hand-waving.
It's simply defined by the equations which define it. These definitions are useful because as you compute the value for kinetic energy + potential energy + rest mass energy at different times, you find it stays constant over time (assuming you are sticking to a single coordinate system).
rjbeery said:
"The ability to do work" is very common
No, word-definitions aren't how concepts like "energy" are understood in physics.
rjbeery said:
but...you seem to be suggesting that the ability of two objects to do work depends upon who is observing them. This doesn't seem right to me; does it to you?
"Work" is simply defined as the displacement multiplied by the component of force parallel to the displacement, integrated over the path if the force is changing or it's not a straight line. Since displacement is frame-dependent (you can always pick an inertial frame where the endpoints have the same position coordinate so displacement is zero), work is too.

Are you bothered by the fact that the velocity of an object depends on who's observing it? If not, why should you be any more bothered by the fact that work (or energy in general) is frame-dependent?
rjbeery said:
If kinetic energy "actually existed" then I could create something approaching an infinite amount of energy by simply jumping in the air...
The usual Newtonian definition of kinetic energy only applies in an inertial frame, if you jump into the air you move non-inertially. It's true that in your temporary inertial rest frame mid-jump the kinetic energy of the Earth is much larger than the kinetic energy of the Earth in your inertial rest frame while standing, but in each frame the total energy is constant with time, you aren't "creating" energy in any inertial frame.
 
<h2>1. What is the case for True Length = Rest Length?</h2><p>The case for True Length = Rest Length is based on the theory of special relativity, which states that the length of an object appears shorter when it is moving at high speeds. This means that the true length of an object is equal to its rest length when it is not moving.</p><h2>2. How does this theory apply to everyday objects?</h2><p>This theory applies to all objects, regardless of their size or speed. However, the effects are only noticeable when objects are moving at extremely high speeds, such as close to the speed of light.</p><h2>3. Can this theory be tested?</h2><p>Yes, this theory has been extensively tested and has been found to be accurate. One famous experiment that supports this theory is the Michelson-Morley experiment, which showed that the speed of light is the same in all directions, regardless of the motion of the observer.</p><h2>4. Are there any practical applications of this theory?</h2><p>Yes, this theory has many practical applications, particularly in the field of particle physics. It is also important in the design of high-speed transportation systems, such as airplanes and spacecraft.</p><h2>5. Is there any controversy surrounding this theory?</h2><p>While the theory of special relativity has been widely accepted by the scientific community, there are still some debates and controversies surrounding it. Some scientists argue that there may be other factors that could affect the true length of an object, while others believe that this theory is incomplete and needs further development.</p>

1. What is the case for True Length = Rest Length?

The case for True Length = Rest Length is based on the theory of special relativity, which states that the length of an object appears shorter when it is moving at high speeds. This means that the true length of an object is equal to its rest length when it is not moving.

2. How does this theory apply to everyday objects?

This theory applies to all objects, regardless of their size or speed. However, the effects are only noticeable when objects are moving at extremely high speeds, such as close to the speed of light.

3. Can this theory be tested?

Yes, this theory has been extensively tested and has been found to be accurate. One famous experiment that supports this theory is the Michelson-Morley experiment, which showed that the speed of light is the same in all directions, regardless of the motion of the observer.

4. Are there any practical applications of this theory?

Yes, this theory has many practical applications, particularly in the field of particle physics. It is also important in the design of high-speed transportation systems, such as airplanes and spacecraft.

5. Is there any controversy surrounding this theory?

While the theory of special relativity has been widely accepted by the scientific community, there are still some debates and controversies surrounding it. Some scientists argue that there may be other factors that could affect the true length of an object, while others believe that this theory is incomplete and needs further development.

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