Exploring the Paradox of Relativity's Speed of Light

In summary: What about referencing movement of a photon?That's what I'm saying..., if c is constant to any observer, then isn't each observer moving at that constant c relative to the light?Please start by reading the FAQ subforum in the Relativity forum.
  • #36
DrDon said:
Okay..., that's what I had assumed the answer would be. But it brings up the question, why specific "at rest"? From the sounds of your response, whether I'm walking or not walking, it's all the same.

Im gunna throw a guess out there and say it's because..., again, c is constant. As you accelerate your measurements change as your velocity changes relative to what they once were.

Again, not from math, I think the graphical representation is 4 dimensions, you either move through time (rest frame) or space & time. So as you continue to accelerate, your frame of spacetime properties are changing from what they once were, c is staying the same. If you stay still, you will have constant whatever properties (momentum, and other junk) and will again have the opportunity to measure c on a level playing field.

Is that right'ish Pengwuino? or anyone
 
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  • #37
DrDon said:
DrGreg, your response brings up a tangent question I hope you (or others) can answer -- a question I don't recall thinking of before. Accepting that I, as an at-rest observer (but "at rest" relative to what?), see a light beam approaching me at c, if I were to towards or away from that beam, would I still see it at c, or at c plus/minus my own velocity?

Vector addition is different in SR than the one in euclidean space: http://en.wikipedia.org/wiki/Velocity-addition_formula#Special_theory_of_relativity
 
  • #38
nitsuj said:
Im gunna throw a guess out there and say it's because..., again, c is constant. As you accelerate your measurements change as your velocity changes relative to what they once were.

Again, not from math, I think the graphical representation is 4 dimensions, you either move through time (rest frame) or space & time. So as you continue to accelerate, your frame of spacetime properties are changing from what they once were, c is staying the same. If you stay still, you will have constant whatever properties (momentum, and other junk) and will again have the opportunity to measure c on a level playing field.

Is that right'ish Pengwuino? or anyone

I can't exactly understand what you're trying to say.

WannabeNewton said:
Vector addition is different in SR than the one in euclidean space: http://en.wikipedia.org/wiki/Velocity-addition_formula#Special_theory_of_relativity

This isn't really what he's asking since velocity addition in that sense talks about moving between different frames of reference and measuring massive particles movement. If you're looking at how the speed of light changes as you move at constant velocities, it doesn't.
 
  • #39
WannabeNewton said:
Well the speed of light is measured as c in inertial frames, or locally flat space i.e. where the general metric reduces to the minkowski metric, so global measurements wouldn't give c because you can't even define velocity properly globally due to the path dependence of parallel transport.

If you call that a measurement so be it.
 
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  • #40
Pengwuino said:
I can't exactly understand what you're trying to say.

To say it differently, as you accelerate that Lorentz transformation thing happens. I imagine as you "continuously" accelerate the transformations occur congruently and that is what would spoil the measurements in calculating c is constant. (at rest you are in the same "frame" as c, proper time)
 
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  • #41
Pengwuino said:
This isn't really what he's asking since velocity addition in that sense talks about moving between different frames of reference and measuring massive particles movement. If you're looking at how the speed of light changes as you move at constant velocities, it doesn't.

He asked if he would measure a speed of light greater or less than c if he were to move along with or away from a beam of light and the reason it remains c no matter what is easily seen through the velocity - addition formula of SR.
 
  • #42
DrDon said:
DrGreg, your response brings up a tangent question I hope you (or others) can answer -- a question I don't recall thinking of before. Accepting that I, as an at-rest observer (but "at rest" relative to what?), see a light beam approaching me at c, if I were to towards or away from that beam, would I still see it at c, or at c plus/minus my own velocity?
Have you ever thought about what it means to "see a light beam approaching" you and how you would measure its speed? Has it occurred to you that you cannot see the beam, all you can see is the portion of it when it reaches you? If you're thinking about seeing a beam from a search light, for example, the only reason why you can see it as a beam is because there are dust particles in the air that are illuminated by the beam itself and then scattered in all directions and you're seeing the ones that are scattered in your direction. But if you were in the vacuum of space, you would not see any beam; you would just see the spot where it hits your eye or your detector. It may look like it is coming from a source far away, but you cannot see the image of that source until the light from it reaches you, correct?

So now, how do you measure its speed since you cannot see it until it reaches you? First off, it doesn't matter if you are "at rest" relative to anything, just that you are not accelerating. Secondly, you don't have to worry about any frame of reference or any theory about relativity or ether or anything else. Thirdly, you don't have to worry about the source of light, just that it is not accelerating, which just means that it is not changing.

Now in order to actually measure the speed of light coming from a fixed distant source, you need to have some equipment. Since speed is length divided time, you need to have a rigid measuring stick of a known fixed length and a timing device. Since the beam is coming at you all the time, you also need a shutter so that you can start and stop the beam to give you something to observe and know when the light has traveled a certain distance. One last thing you need is a mirror. So you fix your shutter at one end of your measuring stick along with your timer which you start together. The pulse of light now travels to the other end of your measuring stick where it reflects off the mirror and back to you where you have a light detector that stops the timer. Then you calculate the speed of light as twice the distance between your shutter/detector and your mirror, divided by the time interval. The value that you get will be c.

Now you fire your rockets and head toward the light source until you reach whatever speed you want. You turn off your thrusters and you repeat your measurement exactly as you did before and you get the exact same value for the speed of light.

Now you turn your rocket around and head away from the light source until you are going in the other direction from your first measurement and go as fast as you want. You stop, turn around and repeat the measurement. You get the same answer.

Do you accept this as a factual statement of what would really happen if you could carry out this experiment?
 
  • #43
WannabeNewton said:
He asked if he would measure a speed of light greater or less than c if he were to move along with or away from a beam of light and the reason it remains c no matter what is easily seen through the velocity - addition formula of SR.

Hmm, I seem to enjoy complicating things beyond what's needed and possibly making them nonsensical. You're right.
 
  • #44
DrDon said:
Accepting that I, as an at-rest observer (but "at rest" relative to what?), see a light beam approaching me at c, if I were to towards or away from that beam, would I still see it at c, or at c plus/minus my own velocity?

I think it would be at rest to time itself. c. rate/flow,ect At one with the continuum :smile:

Qm seems to say that it's impossible to predict velocity/position and some other things simultaneously. Almost like it is physically impossible to pin down the point of "now" (as we know it).
 
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  • #45
Pengwuino said:
It's usually the simplest. Walking at constant velocity works as well perfectly fine (which is at the core of special relativity). However, if you accelerate, you no longer are an inertial observer and everything mentioned already no longer applies. When you talk about accelerations, you can no longer freely move between frames of reference and see the same physics occurring.

Okay, so the only real distinction that need to be made is accelerating or not accelerating (which differentiates using SR or GR). Other distinctions do not matter. I can go with that.
 
  • #46
ghwellsjr said:
Have you ever thought about what it means to "see a light beam approaching" you and how you would measure its speed? Has it occurred to you that you cannot see the beam, all you can see is the portion of it when it reaches you? ...

Forgive me, for I have taken the lazy route and not stated myself as specifically as I suppose I should have. I was not particularly interested in all the mechanics. Rather, I simply wanted to know that as light approached me at c (relative to me) while I am "at rest", would that relative-to-me speed change if I were no longer at rest (e.g., if I were walking towards or away from the beam). What I really saw, or did not see, was really a mute point. My apologies if my casual description conveyed the wrong idea.
 
  • #47
DrDon said:
I simply wanted to know that as light approached me at c (relative to me) while I am "at rest", would that relative-to-me speed change if I were no longer at rest (e.g., if I were walking towards or away from the beam).
The phrase "relative to me" means "in the frame where I am at rest". In that frame it makes no sense to speak of walking towards or away from the beam. You are stationary in that frame by definition.
 
  • #48
DrDon said:
as light approached me at c (relative to me) while I am "at rest", would that relative-to-me speed change if I were no longer at rest (e.g., if I were walking towards or away from the beam).

No. Regardless of whether you are standing still, or walking towards or away from the source of the light, or running towards or away from it, or flying in a spaceship at 0.9c towards or away from it, the light always moves at c towards you.
 
  • #49
jtbell said:
No. Regardless of whether you are standing still, or walking towards or away from the source of the light, or running towards or away from it, or flying in a spaceship at 0.9c towards or away from it, the light always moves at c towards you.

Thanks. Like I mentioned to an earlier reply, this is what I thought relativity held to; but the regular mention of an object being "at rest" made me question this, and so I just needed verification.
 
  • #50
Has your original question been answered?
 
  • #51
ghwellsjr said:
Has your original question been answered?

Thanks for asking. I would have to answer your question is both yes and no. The "yes" part is that, I'm told, that light has not ref. frame, and thus my movement relative to it and can not be determined. The "no" part is this: at any micro-fraction of a nano second the distance between the beam and me is a definite, measurable distance. Thus, at both T1 and T2 (Time 1 and Time 2) that distance can be measured, and with delta D factored with delta T, a speed can be determined at which, relative to the beam, I am moving (or, conversely, it is moving relative to me). Maybe this is something that I just have to accept for now.
 
  • #52
DrDon said:
Thanks for asking. I would have to answer your question is both yes and no. The "yes" part is that, I'm told, that light has not ref. frame, and thus my movement relative to it and can not be determined. The "no" part is this: at any micro-fraction of a nano second the distance between the beam and me is a definite, measurable distance. Thus, at both T1 and T2 (Time 1 and Time 2) that distance can be measured, and with delta D factored with delta T, a speed can be determined at which, relative to the beam, I am moving (or, conversely, it is moving relative to me). Maybe this is something that I just have to accept for now.

But these are your distances and times, and lead to you computing the light moves at c. You need to ask about the light's measurements of distance and time, which you've been told are undefinable. In the limit as v->c, you get 0/0.
 
  • #53
DrDon said:
Thanks for asking. I would have to answer your question is both yes and no. The "yes" part is that, I'm told, that light has not ref. frame, and thus my movement relative to it and can not be determined. The "no" part is this: at any micro-fraction of a nano second the distance between the beam and me is a definite, measurable distance. Thus, at both T1 and T2 (Time 1 and Time 2) that distance can be measured, and with delta D factored with delta T, a speed can be determined at which, relative to the beam, I am moving (or, conversely, it is moving relative to me). Maybe this is something that I just have to accept for now.
If you're going back to my description of how to measure the speed of a light beam from post #42 and you are concerned about the time it takes for the shutter/detector to transmit the start (at T1) and stop (at T2) signals to the timer, as long as it is the same for both times, then it won't have any bearing on delta T, the difference beween between T2 and T1.

If you're not going back to post #42, then I have no idea what you're talking about so could you elaborate?
 
  • #54
PAllen said:
But these are your distances and times, and lead to you computing the light moves at c. You need to ask about the light's measurements of distance and time, which you've been told are undefinable. In the limit as v->c, you get 0/0.

So, you're saying that due to the warp in time/space from the light's traveling at c, the distance from me to the light beam is different from my perspective than it is from the light's perspective? Guess I hadn't grasped that part of relativity before.

I don't know if you've noticed, but I ask a question about this 0/0 (based upon DH's FAQ article) in a separate thread.
 
  • #55
ghwellsjr said:
If you're not going back to post #42, then I have no idea what you're talking about so could you elaborate?

It seems that PAllen identified my problem area (post #52).
 
  • #56
DrDon said:
I'm a relative newbie to relativity (no pun intended -- I know you've heard that one too many times), as well as to this forum, so forgive me if this is a dumb question...

As I understand it, there is a significant percentage of those that believe that people, spaceships, etc. will never travel at the speed of light (c), right?

If that is so, where is my logic (below) faulty:

1. For any two given things (A and B), the speed of A relative to B will always be the same as the speed of B relative to A.

2. Relativity insists that light always travels at c relative to all things.

Thus, if light is moving at c relative to me, then am I not moving at c relative to that particular beam of light (...and, in fact, all beams of light at any given moment in time)? And thus, the speed of light is not only something that is not unattainable, but has rather never been unattained?

What am I missing?

CMIIW
isnt one of einstein postulate said that the speed of light is constant independant of the observer, or in other words the speed of light is just the same for any observer.
 
  • #57
DrDon said:
1. For any two given things (A and B), the speed of A relative to B will always be the same as the speed of B relative to A.
This is because the inverse of a boost is a boost of the same speed (and opposite direction).

DrDon said:
2. Relativity insists that light always travels at c relative to all things.

Thus, if light is moving at c relative to me, then am I not moving at c relative to that particular beam of light
There is no boost to c.

Another way to think of it is that there is a symmetry between two massive observers. There is no sense in which one is "at rest" that doesn't apply equally well to the other, i.e. each can be boosted into a frame where the spacelike components of its four-velocity are 0. There is no such symmetry between a massive observer and light, the massive observer is timelike and the light is lightlike. Light cannot be boosted into a frame where the spacelike components are non-zero.
 
  • #58
PAllen said:
But these are your distances and times, and lead to you computing the light moves at c. You need to ask about the light's measurements of distance and time, which you've been told are undefinable. In the limit as v->c, you get 0/0.

After sleeping on this, I suppose that ultimately what you are saying is that Statement 1 of my original post in this thread (1. For any two given things (A and B), the speed of A relative to B will always be the same as the speed of B relative to A) -- a statement that I think I picked up for Einstein's own material -- is not always true. Specifically, for currently attainable speeds it is true, but as an object approaches the speed of light this becomes less and less true. Would that be a fair conclusion..., and thus point out the flaw in the original logic?
 
  • #59
DrDon said:
After sleeping on this, I suppose that ultimately what you are saying is that Statement 1 of my original post in this thread (1. For any two given things (A and B), the speed of A relative to B will always be the same as the speed of B relative to A) -- a statement that I think I picked up for Einstein's own material -- is not always true. Specifically, for currently attainable speeds it is true, but as an object approaches the speed of light this becomes less and less true. Would that be a fair conclusion..., and thus point out the flaw in the original logic?

No, it is exactly true for any speed less than c. It is meaningless for c. The relativity statement you are mis-quoting was between material bodies which always move less than c relative to each other. You have the following properties, actually:

1) If B is moving relative to A at less than c, then A's motion relative to B is the same (in the opposite direction).

2) If B is moving at c relative to A, it is moving at c relative to all matter, and there is no such thing as motion relative to B. Further, B has no rest mass and no rest frame.
 
<h2>What is the paradox of relativity's speed of light?</h2><p>The paradox of relativity's speed of light refers to the fact that according to Einstein's theory of relativity, the speed of light is constant and the same for all observers, regardless of their relative motion. This contradicts our everyday experience, where the speed of objects is affected by their motion and the motion of the observer.</p><h2>How did Einstein discover this paradox?</h2><p>Einstein discovered this paradox through his thought experiments and mathematical equations. He realized that the laws of physics should be the same for all observers, regardless of their relative motion. This led him to the conclusion that the speed of light must be constant for all observers.</p><h2>What are the implications of this paradox?</h2><p>The implications of this paradox are far-reaching and have revolutionized our understanding of the universe. It has led to the development of the theory of relativity, which has been confirmed by numerous experiments and is the basis for modern physics. It also has implications for our understanding of time, space, and the nature of reality.</p><h2>How is this paradox relevant in modern science?</h2><p>This paradox is extremely relevant in modern science as it forms the basis of our understanding of the universe. The principles of relativity have been applied in various fields, including astrophysics, quantum mechanics, and cosmology. It has also led to the development of technologies such as GPS, which relies on the precise measurements of time and space.</p><h2>Is there a resolution to this paradox?</h2><p>While the paradox of relativity's speed of light may seem counterintuitive, it has been confirmed by numerous experiments and is considered to be a fundamental law of the universe. While there may be ongoing debates and discussions about its implications, there is currently no known resolution to this paradox.</p>

What is the paradox of relativity's speed of light?

The paradox of relativity's speed of light refers to the fact that according to Einstein's theory of relativity, the speed of light is constant and the same for all observers, regardless of their relative motion. This contradicts our everyday experience, where the speed of objects is affected by their motion and the motion of the observer.

How did Einstein discover this paradox?

Einstein discovered this paradox through his thought experiments and mathematical equations. He realized that the laws of physics should be the same for all observers, regardless of their relative motion. This led him to the conclusion that the speed of light must be constant for all observers.

What are the implications of this paradox?

The implications of this paradox are far-reaching and have revolutionized our understanding of the universe. It has led to the development of the theory of relativity, which has been confirmed by numerous experiments and is the basis for modern physics. It also has implications for our understanding of time, space, and the nature of reality.

How is this paradox relevant in modern science?

This paradox is extremely relevant in modern science as it forms the basis of our understanding of the universe. The principles of relativity have been applied in various fields, including astrophysics, quantum mechanics, and cosmology. It has also led to the development of technologies such as GPS, which relies on the precise measurements of time and space.

Is there a resolution to this paradox?

While the paradox of relativity's speed of light may seem counterintuitive, it has been confirmed by numerous experiments and is considered to be a fundamental law of the universe. While there may be ongoing debates and discussions about its implications, there is currently no known resolution to this paradox.

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