tomclarke wrote:Well, would it help if I posted the math? Of course, since you don't give any reasons for rejecting my statements above I guess anything I post is not likley to challenge your views.
The experimental evidence is with me, you know...
303 wrote:i think you should post the math
happyjack , whats the furthest apart the two slits have been and the interference pattern still occurs , does the singularity cause a shockwave or resonance in the em field?
happyjack27 wrote:tomclarke wrote:Well, would it help if I posted the math? Of course, since you don't give any reasons for rejecting my statements above I guess anything I post is not likley to challenge your views.
The experimental evidence is with me, you know...
i've already posted the math to prove what i'm saying. the case was closed a long time ago - decades ago, in fact.
303 wrote:i think you should post the math
happyjack , whats the furthest apart the two slits have been and the interference pattern still occurs , does the singularity cause a shockwave or resonance in the em field?
tomclarke wrote:303 wrote:i think you should post the math
happyjack , whats the furthest apart the two slits have been and the interference pattern still occurs , does the singularity cause a shockwave or resonance in the em field?
I'll do the easier one!
A is stationary twin, B is twin who travels as speed v (relative to A) to alpha centauri and then at speed v back. Suppose B clock shows elapsed time T during journey from earth to alpha centauri.
LT transforms between A and B clocks.
Since A frame stays constant (fixed newtonian frame) we can use A's transformation of B clock consistenctly through journey to compare times.
Note we can't do the reverse so simply since B's frame changes, which means a correction must be made at the frame change to B's transformation of A's clock.
we know that A clock changes by T/gamma during outward journey as B clock changes by T (the subjective journey time).
gamma = 1/(sqrt(1-v^2/c^2).
Similarly on the return journey. Although the speed and therefore LT is different, the coefficient between A and B times is the same , and there is no change in the B clock time as transformed into A frame during the turnaround.
Therefore total elapsed time on clocks when they meet is:
B: 2T
A: 2T/gamma > 2T
Note I'm assuming here that v is high enough for this effect to be much larger than any GR effects due to gravity well (which would make A clock read slightly slower than B clock).
This proves my statement about proper time of "bent" path being less than proper time of stright path between same two points with timelike separation. (the points here are the B leaving A and B returning to A events).
Best wishes, Tom
happyjack27 wrote:tomclarke wrote:happyjack27 wrote:johan is saying that in the absence of general relativity, each observer will read the same time on _their own_ clocks. this will be different than what they read on _each other_'s clocks. however, likewise, the time a reads on b's clock will match the time b reads on a's clock.
this symmetry is gauraunteed by the fact that the paths they see each other travel are only differ by a rotation and/or reflection.
however, if you follow this logic mathematically, and aren't very careful, it seems to imply that a<>a, hence the term "twin paradox". a=b, a'=b', a>b', b>a' does not imply a contradiction, but if you simply remove the prime ('), it does.
That is all true, for two clocks both on "unbent" trajectories.
When one of the trajectories is bent the symmetry no longer exists, but if you assume it does, you argue as Johan that the two clocks must read the same time when they come together. That would be trivially so were the situation symmetrical.
When calculating this case using LT there is a correction that must be made to the calculated time of the far clock when the frame in which this is calculated changes.
Best wishes, Tom
what's this "bent" trajectory thing? you talking about curved space i.e. gravity? i'm talking about in the absence of gravity, any trajectory, "bent" or "unbent", spirals swirls hammerheads sharp right turns, oscillations, whatever. i am talking about what's, in technical parlance, is called A TRAJECTORY. REFERENCE FRAME A'S TRAJECTORY FROM THE POINT OF VIEW OF REFERENCE FRAME B IS THE SAME AS REFERENCE FRAME'S B'S TRAJECTORY FROM THE POINT OF VIEW OF REFERENCE FRAME A EXCEPT FOR A SINGLE 180 DEGREE ROTATION AND/OR A SINGLE REFLECTION. what part of that is so god-damned difficult for you to understand?!?!
happyjack27 wrote:tomclarke wrote:303 wrote:i think you should post the math
happyjack , whats the furthest apart the two slits have been and the interference pattern still occurs , does the singularity cause a shockwave or resonance in the em field?
I'll do the easier one!
A is stationary twin, B is twin who travels as speed v (relative to A) to alpha centauri and then at speed v back. Suppose B clock shows elapsed time T during journey from earth to alpha centauri.
LT transforms between A and B clocks.
Since A frame stays constant (fixed inertial frame) we can use A's transformation of B clock consistently through journey to compare times.
Note we can't do the reverse so simply since B's frame changes, which means a correction must be made at the frame change to B's transformation of A's clock.
we know that in A's frame A clock changes by T*gamma during outward journey as B clock changes by T (the subjective journey time).
gamma = 1/(sqrt(1-v^2/c^2).
Similarly on the return journey. Although the speed and therefore LT is different, the coefficient between A and B times is the same , and there is no change in the B clock time as transformed into A frame during the turnaround.
Therefore total elapsed time on clocks when they meet is:
B: 2T
A: 2T*gamma > 2T
Note I'm assuming here that v is high enough for this effect to be much larger than any GR effects due to gravity well (which would make A clock read slightly slower than B clock).
This proves my statement about proper time of "bent" path being less than proper time of stright path between same two points with timelike separation. (the points here are the B leaving A and B returning to A events).
Best wishes, Tom
ok, now do it from B's reference frame.
happyjack wrote:johan is saying that in the absence of general relativity, each observer will read the same time on _their own_ clocks. this will be different than what they read on _each other_'s clocks. however, likewise, the time a reads on b's clock will match the time b reads on a's clock.
this symmetry is gauraunteed by the fact that the paths they see each other travel are only differ by a rotation and/or reflection.
however, if you follow this logic mathematically, and aren't very careful, it seems to imply that a<>a, hence the term "twin paradox". a=b, a'=b', a>b', b>a' does not imply a contradiction, but if you simply remove the prime ('), it does.
happyjack27 wrote:utterly pointless.
happyjack wrote:REFERENCE FRAME A'S TRAJECTORY FROM THE POINT OF VIEW OF REFERENCE FRAME B IS THE SAME AS REFERENCE FRAME'S B'S TRAJECTORY FROM THE POINT OF VIEW OF REFERENCE FRAME A EXCEPT FOR A SINGLE 180 DEGREE ROTATION AND/OR A SINGLE REFLECTION
charliem wrote:Tom, you base your reasoning in that for twins to reunite one (or both) has to abandon his initial inertial FOR, and if only one of them does so that asymmetry justifies the age difference when they meet.
But what if we make a different experiment (without twins), one in which no one abandon their initial inertial FORs at any moment?
An observer OB stays in its own inertial FOR all the time. A ship S1 pass it at high relative speed, at the moment of maximum approximation S1 synchronizes an on board clock with another in OB.
S1 never changes speed. Some time later it crosses with another ship S2, inbound toward OB. At the moment of maximum approximation S2 synchronizes its clock with the one in S1.
When S2 gets near OB their respective clocks are compared (without decelerating).
What's the result? Do both clocks, the one that remained in OB and the one that came in S2, give the same time?
tomclarke wrote:Thus the S1/S2 clock time is identical to the previous B time, and shorter than the OB time. However you cannot calculate the elapsed time of OB clock from S1/S2 without a time shift correction, just the ame as in the B case.
charliem wrote:tomclarke wrote:Thus the S1/S2 clock time is identical to the previous B time, and shorter than the OB time. However you cannot calculate the elapsed time of OB clock from S1/S2 without a time shift correction, just the ame as in the B case.
Sorry Tom, I don't follow you there.
Do you mean that when they compare OB's and S2's clocks they say the same time, or that S2's clock is behind?
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