Doc Al said:Of course he 'acknowledges' that he and Harriet are in relative motion. But that's got nothing to do with his measurement of the distance between the clocks, since the clocks are at rest with respect to him.
Nope. The concept of "really" moving is meaningless. There is only relative motion.aintnuthin said:Well, I guess I'm not sure what is unclear here. My logic is kinda like this.
1. If any two objects are moving with respect to each other, at least one of them must be "really" moving, even if both are always "at rest" with respect to themselves.
Nope.2. Maybe you know who's really moving, maybe you don't, but, either way, you know one of the two is.
Nope.3. If you don't "know" then let's say the odds are 50-50 that you are moving with respect to the other, and that it is "stationary" with respect to you.
Nope. An observer always measures things from his own frame.Everyday example: I am going down the freeway at 60 mph. As between me and the road, I know ONE of us is (relatively) stationary and that one of us is (relatively) moving. In that case, I would assume that I'm the one moving relative to the road (and all other fixed things on the planet that I see), not that they are all coming to, and going past, me. In such a case I would NOT employ the LT from the perspective that *I* was stationary and that something fixed (say a tree) that was "approaching" me was "really moving."
Yep. All wrong.On the contrary, I would employ my knowledge of SR (such as it is) to calculate times and lengths from "in reverse." I would assume that Earth's clocks would be faster (not slower) than mine and that it's lengths would be longer (not shorter) than mine are in my frame. That, for example, there would be some (however infintesimal) difference in the rate at which my watch keeps time, and the rate it keeps time when I come to a stop sign. As I sped up, I would assume that my watch was running slower than the one I saw the guy standing at the stop sign wearing. I would assume that his watch was now faster than mine, and mine slower than his. Would I be wrong to make such assumptions?
All you need to know is the relative speed between the two frames.aintnuthin said:I agree, it doesn't affect the measurements that I make in my frame in the least. But it could affect how I attempt to impute (transform) those measurements to her frame via calculation, couldn't it?
This is wrong, you must get rid of this idea. It completely misses the point of relativity, not just Einstein's special relativity but also Galilean relativity of classical physics.aintnuthin said:Well, I guess I'm not sure what is unclear here. My logic is kinda like this.
1. If any two objects are moving with respect to each other, at least one of them must be "really" moving, even if both are always "at rest" with respect to themselves.
Doc Al said:Nope. The concept of "really" moving is meaningless. There is only relative motion.
Nope.
Nope.
Nope. An observer always measures things from his own frame.
The only 'assumption' is the relative motion between the frames.aintnuthin said:As i said (next), I agree that an observer always measures things from his own frame. But, likewise, he always imputes (to others) from his own frame, too. How, and what, he imputes would seem to depend on his assumptions.
Yes. You are mixing up measurements in different frames. The key problem is your assumption that one of the frames is 'really' at rest. See DaleSpam's response.Doc, that's sure a lot of "nopes," without any elaboration on your part. Is what I'm suggesting impossible?
DaleSpam said:This is wrong, you must get rid of this idea. It completely misses the point of relativity, not just Einstein's special relativity but also Galilean relativity of classical physics.
Even in Newtonian physics there is no such thing as "really" moving, only moving relative to something else. This is called the "first postulate" or the "principle of relativity" and has been experimentally verified fact since Galileo's time:
http://en.wikipedia.org/wiki/Principle_of_relativity
It seems that all of your errors stem from this point. This is the fundamental symmetry I was describing above. If you want to learn relativity you definitely need to learn this point well.
Sidetracked?? Until you disabuse yourself of the notion of something 'really' being at rest, don't expect to make much progress.aintnuthin said:I don't agree with them all, but don't wish to get sidetracked on those topics.
Doc Al said:The only 'assumption' is the relative motion between the frames.
Where exactly did I say that? All one can ever say is that something is or isn't stationary with respect to something else. (Of course Harriet, and everyone else, treats themselves as being stationary in their own frame.)aintnuthin said:Doc, this assertion that there is only one assumption has confused me from the outset. After asserting that, initially, you proceded to say Harriet's measurements were determined "because she was stationary."
Your analysis is so simple. I used the Lorentz Transform to analyze the same scenario but as you can see it is very much more complicated although I do get the same answer. Could you provide insight into how you do it so much more easily?DaleSpam said:This conversation has become boring so I will work the problem.
Worldline of clock 1
[tex]x'=0[/tex]
[tex]1.25 (0.6 c t + x) = 0[/tex]
[tex]x=-0.6 c t[/tex]
Worldline of clock 2
[tex]x'=6[/tex]
[tex]1.25 (0.6 c t + x) = 6[/tex]
[tex]x = 4.8 - 0.6 c t[/tex]
So we immediately see that the distance between the clocks is 4.8 lightseconds.
Worldline of Harriet
[tex]x' = 0.6 c t[/tex]
[tex]1.25 (0.6 c t+x)=0.75 c \left(\frac{0.6 x}{c}+t\right)[/tex]
[tex]x = 0[/tex]
Finding the intersection of Harriet's worldline with clock 1 we find:
[tex]0 = -0.6 c t[/tex]
[tex]t = 0[/tex]
Finding the intersection of Harriet's worldline with clock 2 we find:
[tex]0 = 4.8 - 0.6 c t[/tex]
[tex]t = 8/c[/tex]
So we see that the time was 8 seconds.
Claimant B is correct. QED.
I am glad that you liked it!ghwellsjr said:Your analysis is so simple. I used the Lorentz Transform to analyze the same scenario but as you can see it is very much more complicated although I do get the same answer. Could you provide insight into how you do it so much more easily?
One tip for making it more concise. If you are using four-vectors then you can cast the Lorentz transforms as matrices instead of as equations.ghwellsjr said:So now we use the Lorentz Transform on each of these six events in Henry's FoR to see what they are in Harriet's FoR.
First we want to calculate gamma, γ, which is equal to 1/√(1-ß²) where ß is the speed as a fraction of c. So:
γ = 1/√(1-ß²) = 1/√(1-0.6²) = 1/√(1-0.36) = 1/√(0.64) = 1/0.8 = 1.25
Then we use these two formulas for each t and x coordinate:
t' = γ(t-vx/c²)
x' = γ(x-vt)
That makes all of these into matrix multiplications.ghwellsjr said:Now we do the detailed calculations. Some of the events are used twice so we only have to do four sets of calculations.
[0,0]:
t=0 and x=0
t' = γ(t-vx) = 1.25(0-0.6*0) = 0
x' = γ(x-vt) = 1.25(0-0.6*0) = 0
[0,6]:
t=0 and x=6
t' = γ(t-vx) = 1.25(0-0.6*6) = 1.25(-3.6) = -4.5
x' = γ(x-vt) = 1.25(6-0.6*0) = 7.5
[10,0]:
t=10 and x=0
t' = γ(t-vx) = 1.25(10-0.6*0) = 12.5
x' = γ(x-vt) = 1.25(0-0.6*10) = -7.5
[10,6]:
t=10 and x=6
t' = γ(t-vx) = 1.25(10-0.6*6) = 1.25(10-3.6) = 1.25(6.4) = 8
x' = γ(x-vt) = 1.25(6-0.6*10) = 0
For the time dilation your approach is nice and easy.ghwellsjr said:And substituting the coordinates from Henry's FoR to Harriet's FoR:
[0,0] Location of clock1 at start of scenario
[-4.5,7.5] Location of Henry and clock2 at start of scenario
[12.5,-7.5] Location of clock1 at end of scenario
[8,0] Location of Henry and clock2 at end of scenario
[0,0] Location of Harriet and her clock at start of scenario
[8,0] Location of Harriet and her clock at end of scenario
From this you can see that the time from start to end of the scenario for Harriet is 8 seconds.
This is probably the most direct way to get the distance from what is given, but it is still somewhat indirect. The problem is, of course, the relativity of simultaneity. Length is the distance between two worldlines, so when I do a problem that involves length contraction I like to use worldlines instead of events. You can still do that using the four-vector notation:ghwellsjr said:There are many ways that Harriet can measure the distance between Henry's two clocks. Probably the simplest is for her to measure how long it takes between clock1 and clock2 arriving at her location and knowing the speed of the clocks (and Henry) she can calculate the distance as simply the speed multiplied by the time interval. This would be 0.6 times 8 or 4.8 light-seconds.
No worries, it is hard for someone who doesn't understand the principle of relativity to understand the rest of relativity.One Brow said:When I first posted, aintnuthin pretty much assured me you would correct my erroneous notions. Thank you all for the explanations offered. I was not aware he planned on following me here. I won't trouble you again.