Why was the concept of aether discarded in the study of light and motion?

In summary: That is correct. He said that time can change the speed of light, which means that if you measure the speed of light with one clock, and then measure it with another clock that is moving with respect to the first clock, the second clock will measure the speed of light to be different.
  • #1
Adrian07
84
1
Am a bit confused about the speed of light being constant, does this mean that whatever speed I am going at, up to and including the speed of light, I will always measure it as going 300000000 mts/sec faster than myself?
 
Physics news on Phys.org
  • #2
Yes, you will always measure the speed of light to be c with respect to you, regardless of your motion with respect to anything else.
 
  • #3
Adrian07 said:
Am a bit confused about the speed of light being constant, does this mean that whatever speed I am going at, up to and including the speed of light, I will always measure it as going 300000000 mts/sec faster than myself?
Welcome to PF! :smile:

Not necessarily so; and note that you can never reach the speed of light.

If you set up a standard inertial reference system* in the lab, then you will next measure the speed of light in vacuum to be nearly 3E8 m/s wrt that reference system. That is a constant: it is the same in all directions, and independent of the motion of the source. Moreover, you don't need to be at rest in your reference system, and neither has the light detector to be at rest in that system.

Many people (even teachers) confound that "constant" with a different kind of constancy, which is that the speed of light is invariant. With that is meant that if you measure light - even coming from the same source - with another standard reference system that is in uniform motion relative to the first, you will again find the same speed.

Now, if you do what you seem to suggest - take your physical system out of your lab and in your car, and measure the one-way speed of entering light rays while you are driving - then you may not find the same value. However, after you re-synchronize your on-board clocks at that velocity, then you'll have again a standard reference system if you keep approximately an inertial course. Subsequently you'll find again the standard value.

* For a simple explanation see section 1 of http://www.fourmilab.ch/etexts/einstein/specrel/www/
 
Last edited:
  • #4
harrylin said:
Now, if you do what you seem to suggest - take your physical system out of your lab and in your car, and measure the one-way speed of entering light rays while you are driving - then you may not find the same value.
Are you here talking about the car as an accelerated frame of reference?

For if the car is moving with a constant velocity wrt the lab system, then, certainly, the speed of light will be measured to c inside the car.
 
  • #5
Erland said:
[..] if the car is moving with a constant velocity wrt the lab system, then, certainly, the speed of light will be measured to c inside the car.
Not necessarily so: "clock synchronization" is for each velocity different, so that it isn't a standard reference system anymore (it is not auto-correcting). Therefore I stressed the importance of synchronization at that velocity.

For others who perhaps not understand this, see: http://www.bartleby.com/173/9.html
 
Last edited:
  • #6
harrylin said:
Not necessarily so: "clock synchronization" is for each velocity different, so that it isn't a standard reference system anymore (it is not auto-correcting). Therefore I stressed the importance of synchronization at that velocity.
Do you mean that if we put two synchronized clocks at different places in a car at rest, and then accelerate the car up to a constant velocity, then, after the acceleration, the clocks are no longer synchronized, wrt an observer inside the car?
 
  • #7
harrylin said:
Not necessarily so: "clock synchronization" is for each velocity different, so that it isn't a standard reference system anymore (it is not auto-correcting). Therefore I stressed the importance of synchronization at that velocity.
Do you mean that if we put two synchronized clocks at different places in a car at rest, say one clock in the front seat and one in the back seat, and then accelerate the car up to a constant velocity, then, after the acceleration, the clocks are no longer synchronized, wrt an observer inside the car?
 
  • #8
Erland said:
Do you mean that if we put two synchronized clocks at different places in a car at rest, say one clock in the front seat and one in the back seat, and then accelerate the car up to a constant velocity, then, after the acceleration, the clocks are no longer synchronized, wrt an observer inside the car?
Exactly.

Edit: I doubt however that this can be detected with current technology; a car is too slow and too small.
 
Last edited:
  • #9
So does this mean if I am emitting the light it will always leave me at c whatever speed I am doing? If I am moving at say 1/2 c and measure the light to be leaving me at c how can someone who is not moving still measure that light at c?
You mention clocks and I think I read somewhere that einstein said something about time changing how does that work?
 
  • #10
Adrian07 said:
So does this mean if I am emitting the light it will always leave me at c whatever speed I am doing?
Yes, just like sound: the speed of the emitter does not affect the speed of propagation.
(that is called in the first paper that I linked for you the "second postulate").
If I am moving at say 1/2 c and measure the light to be leaving me at c how can someone who is not moving still measure that light at c?
I think that the question should be phrased the other way round (often a misunderstanding already exists in the question). Someone who is not moving will still measure that light at c, independent of the motion of the source; that is the second postulate, based on a well established theory of electromagnetism and radiation.
So, the question to ask is: how can you, when you are moving, also measure that light at c? And that was indeed the question around 1900. In the introduction of the paper that I linked for you this was said to be "apparently irreconcilable" with the first. How much of it did you read?
You mention clocks and I think I read somewhere that einstein said something about time changing how does that work?
Probably you mean "time dilation". However, for one-way light speed, the first (and main!) change is a man-made change, as explained in the first section of the paper to which I gave you a link. He explains clock synchronisation. Did you understand it?

And did you read my last remark about what happens when you accelerate with such a reference system to a new constant velocity (post #3)? Assuming that you use perfect clocks and that you can measure precisely enough: then without doing a new synchronisation you will not measure light leaving you at c, but at approximately* c-v for light that leaves you straight ahead. And that result is probably just what you would expect. :smile:


*"approximately": still good approximation at 1% of c, but poor at 0.5 c. I now prepared a numeric example if someone is interested
 
Last edited:
  • #11
Have tried to read the link but it seems long winded and difficult to follow.
I assume that inertial means moving at a constant speed.
I am having problems with the fact that the speed of light is not dependant on the speed of the source, whereas normally the speed of something is dependant on its source i.e. if I fire a gun the speed of the bullet depends on the speed and direction of the gun although the speed is always the same relative to the gun. Someone standing still will measure the bullets speed as being different to that of the moving person holding the gun. With light I get the impression that both would measure it as moving at c, is this the case?
As you keep talking about synchronising clocks does time change somehow relative to the person doing the measurement so changing their perception of speed.
 
  • #12
Adrian07 said:
I am having problems with the fact that the speed of light is not dependant on the speed of the source, whereas normally the speed of something is dependant on its source i.e. if I fire a gun the speed of the bullet depends on the speed and direction of the gun although the speed is always the same relative to the gun. Someone standing still will measure the bullets speed as being different to that of the moving person holding the gun. With light I get the impression that both would measure it as moving at c, is this the case?
Yes, exactly.

You might find the following discussion of special relativity easier to follow: Special Relativity. That's the first lecture in a series that covers all the usual relativistic effects, such as time dilation, length contraction, and the relativity of simultaneity.
 
  • #13
Suppose we have two inertial systems S1 and S2 and that S2 moves with velocity u wrt S1, -c<u<c. Also assume that an object O moves with a constant velocity v wrt S2, in a direction parallell to the direction of the motion between S1 och S2. Here -c<=v<=c, so O might be a photon, but it doesn't have to.

Now what is the velocity w of O wrt S1?

In classical physics, we have w= u+v. But this simple addition formula is invalid in SR, where we have the more complicated velocity addition formula:

w=(u+v)/(1+uv/c^2).

If u and v are small compared to c, then the denominator is close to 1, and then this almost reduces to the classical case. For small mundane velocities, the error in the classical formula is not detectable without very advanced instruments.

It can be shown from this SR-formula that w<=c, with equality if and only if v=c or v=-c (we assumed that -c<u<c). So the relative velocity of a light source does not matter, light speed will be measured to c in all inertial systems (yeah yeah Harrylin, the clocks must be synchronized). And a velocity greater than c will never be measured.
 
  • #14
Adrian07 said:
I am having problems with the fact that the speed of light is not dependant on the speed of the source, whereas normally the speed of something is dependant on its source

The speed of sound waves in the air, or water waves on the ocean don't have anything to do with the source. Generally, waves travel at a speed in the medium that depends on the characteristics of that medium, not on anything having to do with the source of the waves.

The difference is that light waves have no medium except space, and space is the same regardless of your frame of reference.
 
  • #15
Doc Al said:
Yes, exactly.

You might find the following discussion of special relativity easier to follow: Special Relativity. That's the first lecture in a series that covers all the usual relativistic effects, such as time dilation, length contraction, and the relativity of simultaneity.

At first sight, that's a nice introduction of the basics. :smile:

Regretfully some of it is misleading, partly because the author postpones the introduction of what it means to set up a reference system (incl. what "speed of light" here means) to after discussing the results of measurements with such a system.
For example, compare "Light travels at c relative to the observer" just before giving a one-way light speed example (as if it's a True Measurement, see also the word "Truth" in the header!), with the Wikipedia article on that same topic:
http://en.wikipedia.org/wiki/One-way_speed_of_light
 
  • #16
Sorry, harrylin, but I believe you are making things even more confusing for a beginner by focusing (as you often do) on one-way speed of light issues.
 
  • #17
Doc Al said:
Sorry, harrylin, but I believe you are making things even more confusing for a beginner by focusing (as you often do) on one-way speed of light issues.
One-way speed is the focus of the OP and I usually try to answer the question of the OP. But I fully agree that for a complete beginner it may be better to explain two-way speed of light measurements first (Fowler's lecture mixes them up however).

Note: on top of that, that lecture spreads misinformation in the introduction concerning MMX, which only in the best case causes threads like https://www.physicsforums.com/showthread.php?t=631954.

It may be a good idea to start a wiki kind of page with links to good web lectures for beginners. Make it a topic on the forum feedback? :smile:
 
Last edited:
  • #18
Doc Al said:
Sorry, harrylin, but I believe you are making things even more confusing for a beginner by focusing (as you often do) on one-way speed of light issues.
Einstein focused on the one-way speed of light issue in his 1905 paper introducing Special Relativity. His second postulate focuses on the one-way speed of light.

Beginners need to understand that when we are talking about measuring the speed of light being equal to c, we are always talking measuring the round-trip speed of light. When we are talking about the one-way speed of light, we are not talking about a measurement but rather an arbitrary assignment, an arbitrary definition, an arbitrary stipulation, an arbitrary assumption, an arbitrary postulate, an arbitrary axiom, according to Einstein.

Look at the OP's question:
Adrian07 said:
Am a bit confused about the speed of light being constant, does this mean that whatever speed I am going at, up to and including the speed of light, I will always measure it as going 300000000 mts/sec faster than myself?

He's asking about measuring the one-way speed of light. We have to assume that he's asking about the speed of light in the direction that he is moving, not in the direction from where he is coming from, otherwise, he would have wondered if the light would be going slower than himself.

If we point out to him that if he measures the round-trip speed of light by putting a mirror in front of him (like Einstein discussed in his 1905 paper), he will get the same answer that he will get if he does the same measurement in the opposite direction by putting the mirror behind him. This usually surprises beginners until they realize that it's the same measurement, the only difference being the two directions of light travel happen in the opposite order.

Then they have to realize that it is impossible to know if it takes the same time for the light to traverse the distance to the mirror as it takes for the reflection to get back to the observer and this is where Einstein's arbitrary assignment of those two times being equal comes in. This is where we get the unmeasurable one-way speed of light being equal to the same value as the measured two-way speed of light--it's by assignment.

This is the foundational basis of Einstein's argument for Special Relativity, both in his 1905 paper and in his 1920 book. I don't understand why we should hide this from beginners. It's how the theory began. I support harrylin's focus and if he hadn't been here prior to now, I would have been.
 
  • #19
ghwellsjr said:
Einstein focused on the one-way speed of light issue in his 1905 paper introducing Special Relativity. His second postulate focuses on the one-way speed of light.

Beginners need to understand that when we are talking about measuring the speed of light being equal to c, we are always talking measuring the round-trip speed of light. When we are talking about the one-way speed of light, we are not talking about a measurement but rather an arbitrary assignment, an arbitrary definition, an arbitrary stipulation, an arbitrary assumption, an arbitrary postulate, an arbitrary axiom, according to Einstein.

Look at the OP's question:


He's asking about measuring the one-way speed of light. We have to assume that he's asking about the speed of light in the direction that he is moving, not in the direction from where he is coming from, otherwise, he would have wondered if the light would be going slower than himself.

If we point out to him that if he measures the round-trip speed of light by putting a mirror in front of him (like Einstein discussed in his 1905 paper), he will get the same answer that he will get if he does the same measurement in the opposite direction by putting the mirror behind him. This usually surprises beginners until they realize that it's the same measurement, the only difference being the two directions of light travel happen in the opposite order.

Then they have to realize that it is impossible to know if it takes the same time for the light to traverse the distance to the mirror as it takes for the reflection to get back to the observer and this is where Einstein's arbitrary assignment of those two times being equal comes in. This is where we get the unmeasurable one-way speed of light being equal to the same value as the measured two-way speed of light--it's by assignment.

This is the foundational basis of Einstein's argument for Special Relativity, both in his 1905 paper and in his 1920 book. I don't understand why we should hide this from beginners. It's how the theory began. I support harrylin's focus and if he hadn't been here prior to now, I would have been.

wait so the speed of the light going to the mirror is not the same as the speed of the light being reflected from the mirror? Only that the total distance over the total time is the same? That kinda makes sense since some energy is lost due to reflecting but I always thought that the amplitude was the lost energy not the velocity
 
  • #20
No, no. Light speed is constant and the same in all directions. What the other posters talk about is just the difficulties in defining and measuring it.
 
  • #21
VegaMan said:
wait so the speed of the light going to the mirror is not the same as the speed of the light being reflected from the mirror?
Nobody, certainly not Einstein, said the speeds were different. The point is that we can't know. We can't measure the difference. We can't tell if they are the same or if they are different. We don't know.[/QUOTE]
VegaMan said:
Only that the total distance over the total time is the same?
With regard to what we can measure, yes, it's only the total distance divided by the total time that always comes out the same.
VegaMan said:
That kinda makes sense since some energy is lost due to reflecting but I always thought that the amplitude was the lost energy not the velocity
No, this has nothing to do with energy or amplitude, only velocity. Have you read Einstein's 1905 paper, especially the first couple of sections?
 
  • #22
Adrian07 said:
Have tried to read the link but it seems long winded and difficult to follow. I assume that inertial means moving at a constant speed.
Only the introduction and part 1, the explanation of how to set distant clocks are essential here. And yes, "inertial" is a term that people nowadays use for "Newtonian" or "Galilean" reference systems, which are systems in uniform rectilinear motion ("frames of reference for which the equations of mechanics hold good").

Of part 1, did you understand how to "synchronise" distant clocks? By means of such synchronisation you make the one-way "speed of light" equal to the measured two-way speed of light. Please be sure to understand that.

Next you may ask how it can be that (according to special relativity) the two-way speed of light is always measured as c. This can be attributed to time dilation and length contraction. From the perspective of relativity theory, those effects take care of maintaining the relativity principle. And how exactly time dilation and length contraction operate in the two-way measurement of light speed is explained on the second page of Doc Al's reference:

http://galileoandeinstein.physics.virginia.edu/lectures/srelwhat.html

Alternatively you could also try Wikipedia:

en.wikipedia.org/wiki/Time_dilation#Simple_inference_of_time_dilation_due_to_relative_velocity


http://en.wikipedia.org/wiki/Length_contraction

I am having problems with the fact that the speed of light is not dependant on the speed of the source, whereas normally the speed of something is dependant on its source i.e. if I fire a gun the speed of the bullet depends on the speed and direction of the gun although the speed is always the same relative to the gun.
Not always "normally": light is not material, in certain ways it's more like sound or water waves than like bullets. The successful theory on which SR is based (Maxwell's electrodynamics), models light as a kind of wave in space. An essential feature of waves is that their speed c is independent of the motion of the source (to the precision that this has been verified).
[..] With light I get the impression that both would measure it as moving at c, is this the case?
As answered before: Yes, if you first synchronised your clocks at that velocity.
As you keep talking about synchronising clocks does time change somehow relative to the person doing the measurement so changing their perception of speed.
Perception of speed relative to what?
 
Last edited:
  • #23
Adrian07 said:
So does this mean if I am emitting the light it will always leave me at c whatever speed I am doing? If I am moving at say 1/2 c and measure the light to be leaving me at c how can someone who is not moving still measure that light at c?

harrylin said:
Yes, just like sound: the speed of the emitter does not affect the speed of propagation.

i have trouble with "just like sound".

it is the case that with both sound and light that the speed of the emitter does not affect the speed of propagation. what must be kept in mind is that the speed of propagation of sound is relative to the medium that sound propagates in. a medium of propagation is necessary for sound. there is no sound in a vacuum. if this medium was whizzing past you (as an observer) at some speed (like with wind), you will measure the speed of sound to be different in the direction of the movement of the medium than in other directions.

but light does not propagate in any medium. there is no aether for light to propagate in. light can propagate in nothing but empty space. there is no physical meaning in nothing nor empty space whizzing by an observer at some speed. it's just that a changing E-field is causing a changing B-field which is causing a changing E-field. etc. once emitted, that's the mechanism for the propagation of the EM radiation. it does that in a vacuum or in air. for that reason, it doesn't matter if the frame of the emitter is whizzing past you at speed c/2 or not. when you are examining this beam of light (and measuring its speed) and someone traveling along with the emitter is examining the very same beam of light, both observers are in an inertial setting, both observers have equal claim to being "at rest" and the laws of physics, including physical constants, should be the same for both observers.

that's why both observers, one riding along with the light emitter and another watching that observer and his emitter fly by, must measure the speed of light emitted to be the same. now that is not the case with sound. if one observer is moving relative to the other, then the medium in which sound propagates cannot be moving at the same velocity for both observers.
 
  • #24
rbj said:
i have trouble with "just like sound".

it is the case that with both sound and light that the speed of the emitter does not affect the speed of propagation. [..] what must be kept in mind is that the speed of propagation of sound is relative to the medium that sound propagates in. [..]
First of all, the second postulate distinguishes SR from ballistic emission theories which just couldn't be made to work correctly.
However, and that was my point but also yours, it was assumed that if a wave appears to propagate isotropically at c relative to one reference system, it cannot also appear to propagate isotropically at c relative to another reference system that is in uniform motion relative to the first. It is because of that consideration that Einstein remarked that the light postulate is "apparently irreconcilable" with the PoR. You seem to have trouble with that remark.
 
  • #25
ghwellsjr said:
Nobody, certainly not Einstein, said the speeds were different. The point is that we can't know. We can't measure the difference. We can't tell if they are the same or if they are different. We don't know.

With regard to what we can measure, yes, it's only the total distance divided by the total time that always comes out the same.

No, this has nothing to do with energy or amplitude, only velocity. Have you read Einstein's 1905 paper, especially the first couple of sections?[/QUOTE]

I have read it (cause it was linked above) but maybe i don't quite comprehend exactly what I am reading.

Basically what I'm getting from the first 2 sections of the paper is that In order to synchronize 2 clocks the time it takes light to travel from A to B must equal the time it takes for light to be reflected from B and arrive back at A. Also, that the distance from A to B and B to A (round trip distance) divided by the time it takes light to originate from A, travel to B, reflect off of B, and travel back to A equals the speed of light. This makes sense if and only if the the distance between points A and B constantly remains the same.

My question is that if these are true then, wouldn't that technically mean that no 2 clocks in motion relative to each other could ever be synchronized?
And if the speed of light is constant, since v = d/t wouldn't that inherently mean that time and distance would end up being dependent on each other instead of independent variables? when referring to points A and B?
 
  • #26
VegaMan said:
Basically what I'm getting from the first 2 sections of the paper is that In order to synchronize 2 clocks the time it takes light to travel from A to B must equal the time it takes for light to be reflected from B and arrive back at A. Also, that the distance from A to B and B to A (round trip distance) divided by the time it takes light to originate from A, travel to B, reflect off of B, and travel back to A equals the speed of light. This makes sense if and only if the the distance between points A and B constantly remains the same.
That is correct.
VegaMan said:
My question is that if these are true then, wouldn't that technically mean that no 2 clocks in motion relative to each other could ever be synchronized?
That is correct.
VegaMan said:
And if the speed of light is constant, since v = d/t wouldn't that inherently mean that time and distance would end up being dependent on each other instead of independent variables? when referring to points A and B?
Yes, that's the importance of Special Relativity. Time is relative, space is relative. We now talk about spacetime where space and time are not independent of each other.
 
  • #27
ghwellsjr said:
That is correct.

That is correct.

Yes, that's the importance of Special Relativity. Time is relative, space is relative. We now talk about spacetime where space and time are not independent of each other.

So as you go faster lengths get smaller? Or does time flow faster? or both?
 
  • #28
VegaMan said:
So as you go faster lengths get smaller? Or does time flow faster? or both?
Once you use Einstein's definition of a Reference Frame, any rigid object that is traveling is length contracted along its direction of motion and it's clocks take longer to tick which means they run slower. But if you transform everything to a different Reference Frame moving at some speed with respect to the first one, the speeds of those objects can be different, meaning their length contractions and time dilations can be different and you can always transform to a frame in which any given object is at rest in which case there will be no length contraction or time dilation.

Also, be aware that any object or ruler that is traveling with an object will have the same length contraction and time dilation so any measurement that is performed on a "moving" object with identically moving rulers and clocks will come out the same no matter which Reference Frame is used.
 
  • #30
ghwellsjr said:
Once you use Einstein's definition of a Reference Frame, any rigid object that is traveling is length contracted along its direction of motion and it's clocks take longer to tick which means they run slower. But if you transform everything to a different Reference Frame moving at some speed with respect to the first one, the speeds of those objects can be different, meaning their length contractions and time dilations can be different and you can always transform to a frame in which any given object is at rest in which case there will be no length contraction or time dilation.

Also, be aware that any object or ruler that is traveling with an object will have the same length contraction and time dilation so any measurement that is performed on a "moving" object with identically moving rulers and clocks will come out the same no matter which Reference Frame is used.

ok, so if I'm traveling at let's say minutely just under the speed of light. To me, from my perspective, nothing changes. Time and space go on as normal? Or is it actually possible to turn on a flashlight and watch the beam of light slowly extend outward in front of me? Wouldn't time technically stop if i were to reach the speed of light? From my perspective in a fast spaceship that reached the speed of light, would i just instantaneously skip over the speed of light "gap" or interval of time until my speed was reduced to that less than the speed of light?

man this is some freaky stuff
 
  • #31
VegaMan said:
ok, so if I'm traveling at let's say minutely just under the speed of light. To me, from my perspective, nothing changes. Time and space go on as normal?
What you're saying is that in some particular Reference Frame, you're traveling at just under the speed of light and yes, everything is normal for you. But, of course, whatever is at rest or traveling at slow speeds in that frame will be traveling at just under the speed of light relative to you so it's not like you can't tell that you are traveling at a high speed.
VegaMan said:
Or is it actually possible to turn on a flashlight and watch the beam of light slowly extend outward in front of me?
How do you watch a beam of light? It's not like watching some kind of projectile traveling away from you for which you shine light on it and the reflected light off the surface of the projectile is what you are actually seeing, correct? Since projectiles travel at a very small fraction of the speed of light, you simply ignore the additional time it takes for the reflected light to get back to you and you approximately "see" the projectile moving away from you.

But you can't do that with light. What you have to do instead is have some portion of the light beam itself reflect off of other things placed at increasing distances away from you but now you can't ignore the additional time it takes for the reflected light to get back to you. And what will it look like? Since the light is making a round trip, when you turn on the flashlight, it will look like the beam is traveling at one-half the speed of light, do you understand that?

Now because you are traveling in the same direction that the beam is traveling, and light is defined to travel at c in the selected Reference Frame, the beam will be traveling very slowly away from you and then after it hits one of the objects out in front of you, the reflected light will travel back to you almost instantly. Remember how you can't tell if the light takes the same amount of time to go away as it does to come back? This is an example of how you can't tell. As far as you are concerned, it won't look any different than when you are at rest in the Reference Frame and the light takes the same amount of time to go away as it does to come back (by definition, not by observation).
VegaMan said:
Wouldn't time technically stop if i were to reach the speed of light?
Didn't you start off your post by saying "To me, from my perspective, nothing changes. Time and space go on as normal?" To which I agreed. So even if you had accelerated from being at rest in the Reference Frame and you spent an enormous amount of energy getting to your high rate of speed, it would be just like you were at rest and you would have to start all over again to get back to your high rate of speed. You could repeat this as often as you wish and you'd be no closer to the speed of light than before you started.

But technically, you can't reach the speed of light, so there is no meaning to your question of what would happen if you were to reach it.
VegaMan said:
From my perspective in a fast spaceship that reached the speed of light, would i just instantaneously skip over the speed of light "gap" or interval of time until my speed was reduced to that less than the speed of light?
Another meaningless question for the same reason.
VegaMan said:
man this is some freaky stuff
Not to me and hopefully not to you some day.
 
  • #32
ghwellsjr said:
What you're saying is that in some particular Reference Frame, you're traveling at just under the speed of light and yes, everything is normal for you. But, of course, whatever is at rest or traveling at slow speeds in that frame will be traveling at just under the speed of light relative to you so it's not like you can't tell that you are traveling at a high speed.

How do you watch a beam of light? It's not like watching some kind of projectile traveling away from you for which you shine light on it and the reflected light off the surface of the projectile is what you are actually seeing, correct? Since projectiles travel at a very small fraction of the speed of light, you simply ignore the additional time it takes for the reflected light to get back to you and you approximately "see" the projectile moving away from you.

But you can't do that with light. What you have to do instead is have some portion of the light beam itself reflect off of other things placed at increasing distances away from you but now you can't ignore the additional time it takes for the reflected light to get back to you. And what will it look like? Since the light is making a round trip, when you turn on the flashlight, it will look like the beam is traveling at one-half the speed of light, do you understand that?

Now because you are traveling in the same direction that the beam is traveling, and light is defined to travel at c in the selected Reference Frame, the beam will be traveling very slowly away from you and then after it hits one of the objects out in front of you, the reflected light will travel back to you almost instantly. Remember how you can't tell if the light takes the same amount of time to go away as it does to come back? This is an example of how you can't tell. As far as you are concerned, it won't look any different than when you are at rest in the Reference Frame and the light takes the same amount of time to go away as it does to come back (by definition, not by observation).

Didn't you start off your post by saying "To me, from my perspective, nothing changes. Time and space go on as normal?" To which I agreed. So even if you had accelerated from being at rest in the Reference Frame and you spent an enormous amount of energy getting to your high rate of speed, it would be just like you were at rest and you would have to start all over again to get back to your high rate of speed. You could repeat this as often as you wish and you'd be no closer to the speed of light than before you started.

But technically, you can't reach the speed of light, so there is no meaning to your question of what would happen if you were to reach it.

Another meaningless question for the same reason.

Not to me and hopefully not to you some day.

ok got it. So hypothetically, suppose we get the technology needed to travel to Proxima Centauri. It's about 4 light years away. We go there and travel from point A (being earth) to point B (being Proxima Centauri) at half the speed of light. Going off what Einstein said, me in the spaceship would perceive time to be traveling like normal, but it wouldn't take me 8 years to get there from MY time. Back on Earth though it would be an 8 year wait (technically 12 years since the first transmission sent out once the ship reaches Proxima Centauri would take 4 years to get back to earth). This sort of doesn't make sense. The distance between here and Proxima Centauri (for the purposes of the example) doesn't change. The velocity also does not change (suppose we got a running head start and only wanted to do a flyby of point B). Yet on the ship, both the distance and the time have changed? Is this correct? Could we actually calculate how long the trip would "feel" like on the ship?
 
  • #33
VegaMan said:
ok got it. So hypothetically, suppose we get the technology needed to travel to Proxima Centauri. It's about 4 light years away. We go there and travel from point A (being earth) to point B (being Proxima Centauri) at half the speed of light. Going off what Einstein said, me in the spaceship would perceive time to be traveling like normal, but it wouldn't take me 8 years to get there from MY time.
That is correct. It would take you 6.9282 years to get there according to your clock.
VegaMan said:
Back on Earth though it would be an 8 year wait (technically 12 years since the first transmission sent out once the ship reaches Proxima Centauri would take 4 years to get back to earth).
That is correct. In the common earth/Centauri rest frame, it takes 8 years to get there but it takes 12 years for the earthlings to see you get there.
VegaMan said:
This sort of doesn't make sense. The distance between here and Proxima Centauri (for the purposes of the example) doesn't change.
In your rest frame, the distance that Proxima Centauri is away from you is not 4 light years but rather 3.4641 light years.
VegaMan said:
The velocity also does not change (suppose we got a running head start and only wanted to do a flyby of point B). Yet on the ship, both the distance and the time have changed? Is this correct? Could we actually calculate how long the trip would "feel" like on the ship?
Yes, that is correct. Your trip will take 6.9282 years and it will feel like 6.9282 years.
 
  • #34
harrylin #3
Now, if you do what you seem to suggest - take your physical system out of your lab and in your car, and measure the one-way speed of entering light rays while you are driving - then you may not find the same value. However, after you re-synchronize your on-board clocks at that velocity, then you'll have again a standard reference system if you keep approximately an inertial course. Subsequently you'll find again the standard value.

The 1-way, 2-way,...n-way speed of light is c.
The relative light speed v/c is the variable, but that's what can't be measured. The observer can't receive the same unidirectional signal he sends (unless he can move faster then light). If he uses a 2nd observer, a 2nd clock is needed and the synchronization problem appears. Despite being unable to measure his absolute speed (he has one, otherwise v/c would be variable and unreliable), he can still achieve a relative synchronization. This is the familiar parallelogram with the skewed axis, seen in Hermanns (aka Minkowski spacetime diagrams,...who needs verboseness). The synchronization does not alter the value of c, it makes the outbound and inbound paths equal, per Einsteins 'stipulation', i.e, it's not a rule of physics, as he clearly states, but a definition (physics by decree). Since the observer can only be coincident with the emission and detection of the reflected signal, only the round trip time is measurable. The time and location of the reflection event is speculation, thus the skewed spatial axis is bogus.
Do you think it's possible to alter distance by setting a clock?
 
  • #35
phyti said:
harrylin #3
[..] The observer can't receive the same unidirectional signal he sends (unless he can move faster then light). If he uses a 2nd observer, a 2nd clock is needed and the synchronization problem appears. [..] Do you think it's possible to alter distance by setting a clock?
Sorry but I can't follow you. A person who has set up a physical reference system uses as many clocks and detectors as he wants (the system that I referred to uses two clocks, typically as detailed in post #7). That has nothing to do with "altering distances".
 
<h2>1. Why was the concept of aether important in the study of light and motion?</h2><p>The concept of aether was important because it was believed to be the medium through which light and other electromagnetic waves traveled. It was thought to be a substance that filled all of space and provided a reference frame for measuring motion.</p><h2>2. What evidence led to the rejection of the idea of aether?</h2><p>Several experiments, including the Michelson-Morley experiment, showed that the speed of light was constant in all directions, regardless of the motion of the observer. This contradicted the idea of aether as a stationary medium and led to its rejection.</p><h2>3. How did the rejection of aether impact our understanding of light and motion?</h2><p>The rejection of aether led to the development of the theory of relativity, which revolutionized our understanding of space, time, and motion. It also paved the way for the modern understanding of electromagnetic waves and the concept of the speed of light as a fundamental constant.</p><h2>4. Are there any modern theories that incorporate the concept of aether?</h2><p>Some theories, such as the Lorentz Ether Theory, still incorporate the concept of aether as a reference frame for measuring motion. However, these theories are not widely accepted and are seen as alternative interpretations of existing evidence.</p><h2>5. Could there be any validity to the concept of aether in light and motion?</h2><p>While the idea of aether has been largely rejected by modern science, there are still some unanswered questions and mysteries surrounding the nature of light and motion. It is possible that future research could uncover new evidence that may challenge our current understanding and potentially revive the concept of aether in some form.</p>

1. Why was the concept of aether important in the study of light and motion?

The concept of aether was important because it was believed to be the medium through which light and other electromagnetic waves traveled. It was thought to be a substance that filled all of space and provided a reference frame for measuring motion.

2. What evidence led to the rejection of the idea of aether?

Several experiments, including the Michelson-Morley experiment, showed that the speed of light was constant in all directions, regardless of the motion of the observer. This contradicted the idea of aether as a stationary medium and led to its rejection.

3. How did the rejection of aether impact our understanding of light and motion?

The rejection of aether led to the development of the theory of relativity, which revolutionized our understanding of space, time, and motion. It also paved the way for the modern understanding of electromagnetic waves and the concept of the speed of light as a fundamental constant.

4. Are there any modern theories that incorporate the concept of aether?

Some theories, such as the Lorentz Ether Theory, still incorporate the concept of aether as a reference frame for measuring motion. However, these theories are not widely accepted and are seen as alternative interpretations of existing evidence.

5. Could there be any validity to the concept of aether in light and motion?

While the idea of aether has been largely rejected by modern science, there are still some unanswered questions and mysteries surrounding the nature of light and motion. It is possible that future research could uncover new evidence that may challenge our current understanding and potentially revive the concept of aether in some form.

Similar threads

  • Special and General Relativity
2
Replies
45
Views
3K
  • Special and General Relativity
Replies
25
Views
2K
Replies
130
Views
7K
  • Special and General Relativity
Replies
13
Views
1K
  • Special and General Relativity
Replies
12
Views
1K
  • Special and General Relativity
Replies
12
Views
1K
  • Special and General Relativity
5
Replies
146
Views
6K
  • Special and General Relativity
Replies
7
Views
938
  • Special and General Relativity
Replies
15
Views
991
  • Special and General Relativity
Replies
29
Views
2K
Back
Top