Rest Length, Coordinate Length, and an argument for True Length

In summary, the conversation discusses the concept of length contraction in the theory of relativity. It is argued that the observed contraction of an object's length is a distorted view of its true length, which can only be observed by an observer at rest with the object. The conversation also touches on the differences between proper and non-proper views of an object in motion, and how they are both equally valid.
  • #1
GregAshmore
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In an earlier thread, I asserted that a rod has one true length, its rest length. If so, then the shorter coordinate length which is measured in some other frame must be somehow untrue. In this thread I argue that the coordinate length is a distorted view of the true length.

In the graphic below (fig. 1), there are two rods, each with a rest length of four units. The horizontal rod is at rest in frame S; the other rod is at rest in frame M. Frame M is moving at 0.6c relative to frame S. In this discussion, the focus will be on the rod in frame M [red], and its coordinate length in frame S [purple].

http://www.how-do-i-know-its-true.net/media/wpmu/uploads/blogs.dir/1/files/2011/02/RodMovementNumbered.png

[1] The rod which is at rest in frame M will always be parallel to the XM axis, no matter at what time the rod is drawn. Thus each instance of the rod in the graphic is parallel to the XM axis.

[2] The view of the rod from frame S (its coordinate length) is horizontal. Therefore, the view is not one view, but a composite of many views. The coordinate length is composed of many snapshots, each snapshot showing a specific point on the rod at a specific time in frame M. In the graphic, four instances of the rod are marked as they cross time TS = 6.68. The four marked points of the rod are at times TM = 5.35, 6.01, 6.67, and 7.33, respectively. The fifth mark, at TM = 7.75, is where the trailing end of the rod crosses TS = 6.68; no instance of the rod is drawn at that point.

[3] As one moves along the view of the rod in frame S, from leading end to trailing end, the time in frame M increases. This means that, in the view as seen from frame S, the trailing end of the rod has traveled farther than the leading end of the rod. This explains, qualitatively, the contracted coordinate length in frame S.

[4] When the velocity is reversed, the effect is the same, as shown in this graphic (fig. 2):

http://www.how-do-i-know-its-true.net/media/wpmu/uploads/blogs.dir/1/files/2011/02/RodMovementReverse.png

[5] The time differential from the leading end to the trailing end is equal to the relative velocity of the two frames multiplied by the rest length of the rod. In this example, (7.75 - 5.35) = 2.4 = 0.6 * 4, where T = ct and V = v/c. This can be better seen in figure 3:

http://www.how-do-i-know-its-true.net/media/wpmu/uploads/blogs.dir/1/files/2011/02/LengthContraction.png

Thus, the apparent contraction of the rod is directly related to the relative velocity of the frames. Taylor and Wheeler show that the contracted length can be developed by integrating from relative velocity 0 to V. (See exercise L-14 in Spacetime Physics.) Their interpretation is that the trailing end of the rod, as seen in frame S, begins to move before the leading end, thus contracting the rod in frame S. (The same is true for each differential segment of the rod. The differential time at each segment is smaller than at the trailing end, thus leading to a contraction proportional to the length.)

The interpretation proposed here is that the integration describes the compressive shifting of the individual snapshots in frame S. The coordinate length of the rod in frame S is thus a distorted view of the rod, while the rod itself is completely unaffected. The rest length of the rod is therefore its one true length.

Of course, the measured coordinate length is the same regardless of the interpretation of the result.
 
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  • #2
In relativity the length of an object doesn't change due to an outside observer traveling at relativistic speeds as it is anyways. For example, a ship traveling 0.6c relative to Earth couldn't make us earthlings observe ourselves to be distorted in the ships direction of motion. I don't think it actually proves that there is no length contraction, but the contraction is only observed differently by different observers.

I think it is key to remember that the length contraction is used to only maintain the constant speed of light. In time dialation, the amount of time you observe another object to expereince has to be a value that makes you see them measure the speed of light to be the same as you do. If they expereince the dilation themselves this wouldn't happen because they measure light to still travel the same 300,000 km/s or so faster than them. So then two observers couldn't see themselves as their measuring rods as being a different length because the measured speed of light is always the same speed faster for both of the two, otherwise the theory would be useless because they would measure different speeds of light with their distorted measureing rods.
 
  • #3
GregAshmore said:
In an earlier thread, I asserted that a rod has one true length, its rest length.
Please define "true."
 
  • #4
GregAshmore,

You are thorough, I'll give you that.

There is the "proper length" of a body, observable by only those who reside at rest in the proper frame of said body.

There is the "contracted length", observable by only those in luminal motion wrt (the proper frame of) the body.

Relative motion allows us to witness the body as it exists "not in its own instant of time", but rather as it exists "across a duration of its own time". Technically, as it exists "over a length of its own worldline" thru spacetime. Temporally, and wrt its own sense of time, FWD points of the moving body lag AFTward points.

That said, its not about "true or real" vs "untrue or apparent". It's about "proper vs non-proper". There is a "proper view" of the body, which can only be obtained while at rest with the body. There also exists a "non-proper (rotated) view" of the body, when seen in motion. Both views are verifiable via measurement (in theory) by the observer. Neither is less real, or less true, than the other. It's all about POV.

There is one point worth mentioning IMO. None of us ever experience ourselves except in the moment. If we do exist in the continuum as luminally moving others record of us, we are unware of this in our own experience. Yet, this alone does not require that the rotated view does not exist, or that it is any less true or real. The mathematics of the theory require it.

Good work though ! Believe me, everyone who understands relativity theory eventually came across your discovery here at one time or another, and questioned it at length. So, you are in good company.

GrayGhost
 
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  • #5
Greg, when you think about two rods with a relative motion between them, do you think that the true speed of both of them is zero? Or do you think that the true speed of both of them is whatever their relative speed is? Or do you think that the true speed of both of them is some smaller identical value but in opposite directions?

I doubt it. I'm going to guess that you have no problem with the concept of relative speed and you realize that even though each one views the other one as traveling in the opposite direction at the same speed, you understand that you cannot then say that the true difference in speed is double their relative speed.

It is a fact that when two rods are in relative motion, you cannot say that both are stationary at the same time and for the same reason, you cannot say that both their true lengths are their rest lengths at the same time. Special Relativity is all about picking a single frame of reference from which to assign locations, dimensions, and times to everything. It is not possible to pick a frame of reference in which both rods will be their rest length.

If we could say that the length of one rod was its true length, then we would also be saying that we have identified the absolute ether rest frame and the true length of the second moving rod would be a contracted length. When you rotate the first rod, since it is stationary in the ether, its true length will remain the same but when you rotate the second moving rod, its true length would be changing, even though its speed is not changing.

So the bottom line is that your effort to attribute "trueness" to a rod's length is no different than an effort to promote an absolute ether rest frame. Is that really what you want to do?
 
  • #6
Hi GregAshmore, none of what you presented here is new, surprising, or unusual. It does not change the way that the term "length" is defined nor does it make anything about that definition invalid.

You are certainly free to adopt the arbitrary personal definition that the term "true length" means the same as the common term "proper length". In fact, you don't need any of the above justification to do so, you can simply assert "I am defining the term 'true length' to mean the proper length". However, since a common term already exists for the concept why not use it? All you are going to accomplish with this approach is to make communication barriers and encourage confusion.
 
  • #7
GregAshmore said:
In an earlier thread, I asserted that a rod has one true length, its rest length. If so, then the shorter coordinate length which is measured in some other frame must be somehow untrue. In this thread I argue that the coordinate length is a distorted view of the true length.

...

The coordinate length of the rod in frame S is thus a distorted view of the rod, while the rod itself is completely unaffected. The rest length of the rod is therefore its one true length.

Of course, the measured coordinate length is the same regardless of the interpretation of the result.
But, DaleSpam, would you also say that Greg is free to call a contracted "measured coordinate length" the "untrue length" or "a distorted view of the true length" and that rods are "completely unaffected" by their accelerations?

I'm saying that when two rods are in relative motion, Greg needs to understand that they cannot both be at rest at the same time, and so it is not a true statement that their "true lengths" are the same as their "rest lengths".
 
  • #8
DaleSpam said:
Hi GregAshmore, none of what you presented here is new, surprising, or unusual. It does not change the way that the term "length" is defined nor does it make anything about that definition invalid.

You are certainly free to adopt the arbitrary personal definition that the term "true length" means the same as the common term "proper length". In fact, you don't need any of the above justification to do so, you can simply assert "I am defining the term 'true length' to mean the proper length". However, since a common term already exists for the concept why not use it? All you are going to accomplish with this approach is to make communication barriers and encourage confusion.

Dalespam,

I have only seen proper length described as length measured between two spacetime points in an inertial frame in which they are simultaneous (SR; more complex in GR). It is invariant given the points (and the implied geodesic between them). Thus one can talk about the proper length of a moving ruler, whose end events will not be simultaneous in the frame of the ruler, but are simultaneous in the frame of the observer seeing the moving ruler.

OP is defining proper length in the frame in which the ruler is at rest, sort of analgous to rest mass. I haven't seen such a definition in any of my books (or in Wikipedia def. of proper length). Seems a somewhat interesting idea.

Can you clarify this terminology?
 
  • #9
Hi Greg,
I agree with your assertion that "a rod has one true length, its rest length.",
but I find your pictures confusing.
You might want to look at <http://arxiv.org/PS_cache/arxiv/pdf/0906/0906.1919v3.pdf>. [Broken]
 
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  • #10
ghwellsjr said:
But, DaleSpam, would you also say that Greg is free to call a contracted "measured coordinate length" the "untrue length" or "a distorted view of the true length" and that rods are "completely unaffected" by their accelerations?
In relativity--both special and general--every observer is always at rest. As a given observer sees it, all other objects are moving; he himself is stationary. What, then, is the meaning of "their accelerations"? And, how can a rod be affected by acceleration if it never accelerates?

I'm saying that when two rods are in relative motion, Greg needs to understand that they cannot both be at rest at the same time, and so it is not a true statement that their "true lengths" are the same as their "rest lengths".
Each rod is at rest, so far as its resident observer is concerned. Each observer says that it is the other rod which is in motion. No one can prove either one of them wrong.
 
  • #11
DaleSpam said:
Hi GregAshmore, none of what you presented here is new, surprising, or unusual. It does not change the way that the term "length" is defined nor does it make anything about that definition invalid.
I didn't expect that I would be the first to interpret length contraction this way. However, I have not seen this interpretation in the books I have read.

The choice to accept or reject the coordinate length as a valid length of the object will be driven by one's philosophy of reality. There is no disagreement as to the result of the measurement.

You are certainly free to adopt the arbitrary personal definition that the term "true length" means the same as the common term "proper length". In fact, you don't need any of the above justification to do so, you can simply assert "I am defining the term 'true length' to mean the proper length".
For me, the issue is the meaning of the measurements. Such questions cannot be resolved by the adoption of a definition.

However, since a common term already exists for the concept why not use it? All you are going to accomplish with this approach is to make communication barriers and encourage confusion.
I'm not trying to change the world. I have no problem with using the accepted terms in all discussions of practical matters.
 
  • #12
clem said:
Hi Greg,
I agree with your assertion that "a rod has one true length, its rest length.",
but I find your pictures confusing.
You might want to look at <http://arxiv.org/PS_cache/arxiv/pdf/0906/0906.1919v3.pdf>.[/QUOTE] [Broken]
Thanks for the link. I've started reading the paper; I'll finish it this evening.

I found the opening paragraph very interesting. I'll bet it gives DaleSpam fits. (I appreciate your point of view, DaleSpam. There is little practical value in a philosophical discussion of "reality". That's why such discussions must be limited to the appropriate times and places.)

We have put the term ‘Lorentz contraction’ in quotes, because, as we will ex-
plain, Lorentz contraction is not what actually occurs for a moving object in
special relativity (SR). This is well known to most physicists, but too often
‘Lorentz contraction’ is given a spurious physical reality.
 
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  • #13
PAllen said:
I have only seen proper length described as length measured between two spacetime points in an inertial frame in which they are simultaneous (SR; more complex in GR). It is invariant given the points (and the implied geodesic between them). Thus one can talk about the proper length of a moving ruler, whose end events will not be simultaneous in the frame of the ruler, but are simultaneous in the frame of the observer seeing the moving ruler.

OP is defining proper length in the frame in which the ruler is at rest, sort of analgous to rest mass. I haven't seen such a definition in any of my books (or in Wikipedia def. of proper length). Seems a somewhat interesting idea.

Can you clarify this terminology?
You are correct. According to my understanding the term "proper length" (or better "proper distance") refers to the invariant interval between two spacelike separated events. Whereas the term "rest length" refers to the length of an object in the reference frame where it is at rest. For massive inertial objects they are equivalent so the distinction is somewhat hazy at times. This is similar to "invariant mass" vs "rest mass".
 
  • #14
GregAshmore said:
The choice to accept or reject the coordinate length as a valid length of the object will be driven by one's philosophy of reality.
One's philosophy of reality is not relevant here. The coordinate length is the length of the object in the given reference frame by definition. There is no question of validity, it is defined as such.

Although you are free to introduce new terms and their definitions you are not free to un-define already defined terms.

GregAshmore said:
For me, the issue is the meaning of the measurements. Such questions cannot be resolved by the adoption of a definition.
Then I don't know what you hope to accomplish by defining your new term "true length".

IMO, the entire discussion is purely semantic and will remain purely semantic while you focus on introducing new words for already defined concepts. You would be better off to simply adopt the existing terminology "coordinate length" and "proper length" and discuss the physics.
 
  • #15
GregAshmore said:
In relativity--both special and general--every observer is always at rest.
I wouldn't say it this way. I would say that for every observer there exists a valid frame where that observer is at rest. However, the observer is no more constrained to use that frame than any other frame.

GregAshmore said:
What, then, is the meaning of "their accelerations"? And, how can a rod be affected by acceleration if it never accelerates.
Acceleration is not relative, particularly not proper acceleration.
 
  • #16
GregAshmore, please listen to what DaleSpam is trying to tell you. You're not accomplishing anything meaningful here.
 
  • #17
DaleSpam said:
You are correct. According to my understanding the term "proper length" (or better "proper distance") refers to the invariant interval between two spacelike separated events. Whereas the term "rest length" refers to the length of an object in the reference frame where it is at rest. For massive inertial objects they are equivalent so the distinction is somewhat hazy at times. This is similar to "invariant mass" vs "rest mass".

Actually, the part I don't quite agree with is that proper length of a massive body is equivalent to rest length as you've (and Greg and the paper linked by Clem) have defined it. Proper length is defined for the object in motion, and is then less than rest length. That is, an observer seeing the massive object in motion perceives a different slice of its world tube as simultaneous than the object's rest frame, and proper length along a cut of this slice will be shorter than proper length along a cut of the simultaneity slice of the object's rest frame. So proper length of a massive object is observer dependent (even though it is invariant *given* a particular simultaneity slice), while rest length is defined as observer independent by the specification that is always computed in the object's rest frame.
 
  • #18
Greg, what do you say about two clocks in relative motion? Do you agree with these comments:

I assert that a clock keeps one true time, its rest time. If so, then the dilated coordinate time which is measured in some other frame must be somehow untrue. I argue that the coordinate time is a distorted view of the true time.

A clock is completely unaffected by acceleration. It is always at rest and keeping its one true time.
 
  • #19
PAllen said:
Actually, the part I don't quite agree with is that proper length of a massive body is equivalent to rest length as you've (and Greg and the paper linked by Clem) have defined it. Proper length is defined for the object in motion, and is then less than rest length. That is, an observer seeing the massive object in motion perceives a different slice of its world tube as simultaneous than the object's rest frame, and proper length along a cut of this slice will be shorter than proper length along a cut of the simultaneity slice of the object's rest frame. So proper length of a massive object is observer dependent (even though it is invariant *given* a particular simultaneity slice), while rest length is defined as observer independent by the specification that is always computed in the object's rest frame.
When you say "proper length between events A and B" it is simply the (spacelike) spacteime interval. When you say "proper length of object A" you are not specifying the events explicitly. The events are then implicitly chosen to be the end points of the object which are simultaneous in the object's frame. At least that is my understanding.
 
  • #20
DaleSpam said:
When you say "proper length between events A and B" it is simply the (spacelike) spacteime interval. When you say "proper length of object A" you are not specifying the events explicitly. The events are then implicitly chosen to be the end points of the object which are simultaneous in the object's frame. At least that is my understanding.

Ok, fine, with that definition. I guess the confusion there is why the paper linked by Clem proposed the term rest length to be unambiguous.
 
  • #21
I've always seen it used in this way, and I've always used it this way ...

The proper length of a body "is its rest length". It's the largest recordable length for a body. The most important thing ... just as in the case of the spacetime interval (where the observer is present at both events), the proper length is an invariant ... all agree. IOWs, the moving contracted length is not a proper length.

The word PROPER, as I've ever seen it used, relates to the POV of that which is being measured. IOWs, it's the measurement result if relativistic effects are non-existent.

GrayGhost
 
  • #22
DaleSpam said:
I wouldn't say it this way. I would say that for every observer there exists a valid frame where that observer is at rest. However, the observer is no more constrained to use that frame than any other frame.
True, an observer is not constrained to use his rest frame only. In the context of ghwellsjr's post, the important thing is that every observer is at rest, if he chooses to be.

Acceleration is not relative, particularly not proper acceleration.
If I understand Born and Einstein correctly, the achievement of general relativity was the "relativization" of acceleration through the equivalence of inertial and gravitational mass.

I have a suspicion that the effort was not entirely successful. The resolution of the twin paradox is based on the fact that one of the two twins is not in an inertial frame--accelerating. Therefore, there is a kind of absolute reality to acceleration, even though Born says that GR does away with it. However, I limit myself to "suspicion" until I learn the math of GR--my next project.

Regardless, my point was that an object at rest does not accelerate. If it is true that every observer may always consider himself to be at rest, then he never accelerates. In that case, I don't know what ghwellsjr means by the effect on an object of the object's acceleration.
 
  • #23
GregAshmore said:
True, an observer is not constrained to use his rest frame only. In the context of ghwellsjr's post, the important thing is that every observer is at rest, if he chooses to be.


If I understand Born and Einstein correctly, the achievement of general relativity was the "relativization" of acceleration through the equivalence of inertial and gravitational mass.

I have a suspicion that the effort was not entirely successful. The resolution of the twin paradox is based on the fact that one of the two twins is not in an inertial frame--accelerating. Therefore, there is a kind of absolute reality to acceleration, even though Born says that GR does away with it. However, I limit myself to "suspicion" until I learn the math of GR--my next project.

Regardless, my point was that an object at rest does not accelerate. If it is true that every observer may always consider himself to be at rest, then he never accelerates. In that case, I don't know what ghwellsjr means by the effect on an object of the object's acceleration.

You may say GR has a lot less 'relativity' in it than SR. It only accomplished that an accelerated object may consider itself at rest in a gravititational field. Similarly, an object at rest in a gravitational field is actually a non-inertial observer, with a real acceleration (relative to any adjacent inertial object; an inertial object would be in free fall).

An object at 'rest' in an accelerating rocket can in no way consider their frame equivalent to an inertial frame. It can be considered equivalent to an observer standing on planet of appropriate gravity.

Note that for measurements over significant distances, even this equivalence breaks down. Accleration and gravity are absolutely distinguishable by the absence of tidal forces in the former case.
 
  • #24
ghwellsjr said:
Greg, what do you say about two clocks in relative motion? Do you agree with these comments:

I assert that a clock keeps one true time, its rest time. If so, then the dilated coordinate time which is measured in some other frame must be somehow untrue. I argue that the coordinate time is a distorted view of the true time.

A clock is completely unaffected by acceleration. It is always at rest and keeping its one true time.
I'm not sure what I think about it. My initial reaction is that distance and time are not interchangeable, so the parallelism which you have drawn between true length and true time will perhaps not hold up under scrutiny. For example, what precisely do you mean by "view of time"?
 
  • #25
bcrowell said:
GregAshmore, please listen to what DaleSpam is trying to tell you. You're not accomplishing anything meaningful here.
I am listening, respectfully.
 
  • #26
GregAshmore said:
The choice to accept or reject the coordinate length as a valid length of the object will be driven by one's philosophy of reality. There is no disagreement as to the result of the measurement.
What does it mean for a length to be "valid"? How is this any different from calling it "true"? You're using language in a way that seems to make sense to you but you can never actually explain to anyone else in a non-circular way, which is a hint that maybe your ideas don't make as much sense as you think they do.
GregAshmore said:
For me, the issue is the meaning of the measurements. Such questions cannot be resolved by the adoption of a definition.
How can a measurement have "meaning", aside from purely practical questions like what physical procedure you must adopt to make a given type of measurement, or what the result of that measurement implies for your predictions about other empirical results? You really need to provide some explicit explanation of how notions like "true", "valid", "meaning" etc. are supposed to apply to physical measurements, perhaps explain in detail the "philosophy of reality" you refer to in an offhand way above.
 
  • #27
GregAshmore said:
[2] The view of the rod from frame S (its coordinate length) is horizontal. Therefore, the view is not one view, but a composite of many views.
Do you think somehow this is not true in the rest frame? The rest frame's view of the rod at a single instant is actually composed of a bunch of different events on worldlines of different parts of the rod, events which occur at different times in some other frame such as S. Unless you think the rod rest frame's definition of simultaneity is more "true" than any other's, the situation seems to be totally symmetric here, each frame's view of "the rod at a single moment" is composed of a set of events which occur at different moments in the other frame.
 
  • #28
GregAshmore said:
there is a kind of absolute reality to acceleration, even though Born says that GR does away with it.
Coordinate acceleration is relative, proper acceleration is absolute.

GregAshmore said:
Regardless, my point was that an object at rest does not accelerate. If it is true that every observer may always consider himself to be at rest, then he never accelerates. In that case, I don't know what ghwellsjr means by the effect on an object of the object's acceleration.
An object at coordinate rest may still undergo proper acceleration. Since proper acceleration is absolute all observers will agree if something is (proper) accelerating, including the observer himself.

I am not sure what this has to do with the OP.
 
  • #29
JesseM said:
Do you think somehow this is not true in the rest frame? The rest frame's view of the rod at a single instant is actually composed of a bunch of different events on worldlines of different parts of the rod, events which occur at different times in some other frame such as S. Unless you think the rod rest frame's definition of simultaneity is more "true" than any other's, the situation seems to be totally symmetric here, each frame's view of "the rod at a single moment" is composed of a set of events which occur at different moments in the other frame.

GregAshmore, I really think JesseM is right about this. Look at a symmetric spacetime diagram of your rod. Except, this time I've imagined a red rod and a blue rod were prepared at rest in the same system, then each rod is made to move at the same speed in opposite directions relative to the rest black coordinate system in the sketch. I've made the sketch symmetric so that the red and blue sketched line lengths correspond to the same distance, and the time coordinates are scaled the same as well.

You could have put in some hyperbolic calibration curves (for both distance and time) with your sketch. Then proper distances and proper times would have been obvious.

Now, who's 3-D cross-section of the universe has cut out the 3-D rod with the "True" length?" Which 3-D rod has the Proper length?

RedBlue_SpaceTime.jpg
 
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  • #30
GregAshmore said:
Regardless, my point was that an object at rest does not accelerate. If it is true that every observer may always consider himself to be at rest, then he never accelerates. In that case, I don't know what ghwellsjr means by the effect on an object of the object's acceleration.

I'd state it this way ...

Although an object at rest does not undergo any proper acceleration, any POV may consider itself the stationary and all others in motion. However if an observer undergoing proper acceleration assumes the stationary, he'll realize that energy considerations are not satisfactory even though the LTs continue to make accurate kinematic predictions.

GrayGhost
 
  • #31
GregAshmore said:
ghwellsjr said:
Greg, what do you say about two clocks in relative motion? Do you agree with these comments:

I assert that a clock keeps one true time, its rest time. If so, then the dilated coordinate time which is measured in some other frame must be somehow untrue. I argue that the coordinate time is a distorted view of the true time.

A clock is completely unaffected by acceleration. It is always at rest and keeping its one true time.
I'm not sure what I think about it. My initial reaction is that distance and time are not interchangeable, so the parallelism which you have drawn between true length and true time will perhaps not hold up under scrutiny. For example, what precisely do you mean by "view of time"?
I mean exactly what you mean when you use the expression "view of length".

In case you haven't noticed, I took some of your sentences and changed "rod" to "clock", "length" to "time", and "shorter" to "dilated". (I hope no one thought I was agreeing with the comments I asked you about.)

I'm not suggesting that distance and time are interchangeable. When an observer views a moving rod and a moving clock, he sees the rod as a shorter length (along the axis of relative motion) but the clock as taking a longer (dilated) time.

I'm just wondering since you have a problem with the observer's view of the rod's shorter length if you also have a similar problem with the observer's view of the clock's longer time?
 
  • #32
ghwellsjr said:
... In case you haven't noticed, I took some of your sentences and changed "rod" to "clock", "length" to "time", and "shorter" to "dilated". (I hope no one thought I was agreeing with the comments I asked you about.)

Yes, I was wondering about that before :) Good to hear you did not agree. I figured you didn't.

GregAshmore,

Another caveate ... the stationary observer inquires via the LTs as to how the moving clock must presently exist. The hands of the clock, if the clock's motion is luminal enough, will be bent. That is, in the stationary observer's moment, the moving clock will denote the entire proper duration over which its contracted self exists, per the stationary POV. Best part, it's all real. It's difficult to swallow this at first, however you'll likely warm up to it in due time, like it or not. While the moving clock is not perceived in its proper state, it's just as real. IOWs, per the theory, its just another POV of that which exists.

GrayGhost
 
  • #33
ghwellsjr said:
But, DaleSpam, would you also say that Greg is free to call a contracted "measured coordinate length" the "untrue length" or "a distorted view of the true length" and that rods are "completely unaffected" by their accelerations?

I'm saying that when two rods are in relative motion, Greg needs to understand that they cannot both be at rest at the same time, and so it is not a true statement that their "true lengths" are the same as their "rest lengths".
Sorry about my delay in responding to this direct question. I had to think about this for a bit.

You are correct that if the proper lenth is defined as the "true length" then any coordinate length would by implication be an "untrue length". While anyone is free to define any new term that they choose to, it seems that using words like "true" and "untrue" adds a certain level of emotional connotation which is not appropriate. It is also not appropriate to assign personal labels to concepts which are not new but already clearly defined and labeled.

There is precedence, for example, the third generation of quarks were originally called "truth" and "beauty" by the discoverers as was their perogative. However, the community as a whole objected to the connotation and changed the names to "top" and "bottom". Now, even the discoverers should use the accepted terminology for the sake of communication and consistency.

Similarly here, the community has already adopted a name for the concept that the OP would like to label "true length". That name is "rest length", and the OP should use that terminology. If the OP comes up with a new concept then it would be acceptable for him to coin a name for the concept, but even then he should probably avoid terms like "true length" with an unwarranted emotional connotation.
 
  • #34
There is precedence, for example, the third generation of quarks were originally called "truth" and "beauty" by the discoverers as was their perogative. However, the community as a whole objected to the connotation and changed the names to "top" and "bottom"

I think the reason for the change was the considerable delay in finding the t quark. During that period people did not want to say that the standard model had beauty but no truth
 
  • #35
Meir Achuz said:
I think the reason for the change was the considerable delay in finding the t quark. During that period people did not want to say that the standard model had beauty but no truth
:rofl: I don't know if that is correct or not, but I do like that explanation very much!
 
<h2>1. What is rest length?</h2><p>Rest length refers to the length of an object when it is not in motion or under any external forces. It is the natural or original length of the object.</p><h2>2. What is coordinate length?</h2><p>Coordinate length is the length of an object as measured in a specific coordinate system. It can change depending on the frame of reference or coordinate system used.</p><h2>3. What is the difference between rest length and coordinate length?</h2><p>The main difference between rest length and coordinate length is that rest length is an intrinsic property of an object, while coordinate length is dependent on the observer's frame of reference. Rest length remains constant, while coordinate length can change depending on the observer's perspective.</p><h2>4. How does rest length relate to true length?</h2><p>Rest length is the same as true length when an object is at rest. However, when an object is in motion or under external forces, its coordinate length may differ from its true length. Rest length is used to calculate the true length of an object in its original state.</p><h2>5. Can rest length and coordinate length be equal?</h2><p>Yes, rest length and coordinate length can be equal in certain cases. This occurs when an object is at rest or moving at a constant velocity, and there are no external forces acting upon it. In this scenario, the coordinate length measured by an observer would be the same as the rest length of the object.</p>

1. What is rest length?

Rest length refers to the length of an object when it is not in motion or under any external forces. It is the natural or original length of the object.

2. What is coordinate length?

Coordinate length is the length of an object as measured in a specific coordinate system. It can change depending on the frame of reference or coordinate system used.

3. What is the difference between rest length and coordinate length?

The main difference between rest length and coordinate length is that rest length is an intrinsic property of an object, while coordinate length is dependent on the observer's frame of reference. Rest length remains constant, while coordinate length can change depending on the observer's perspective.

4. How does rest length relate to true length?

Rest length is the same as true length when an object is at rest. However, when an object is in motion or under external forces, its coordinate length may differ from its true length. Rest length is used to calculate the true length of an object in its original state.

5. Can rest length and coordinate length be equal?

Yes, rest length and coordinate length can be equal in certain cases. This occurs when an object is at rest or moving at a constant velocity, and there are no external forces acting upon it. In this scenario, the coordinate length measured by an observer would be the same as the rest length of the object.

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