Neither. They'll have the same exact age. Is this your "paradox" you were talking about?
Proposal: Time paradox in Special Relativity Theory.
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Neither. They'll have the same exact age. Is this your "paradox" you were talking about?
How would a curved path or acceleration that is small over a long period of time, be different than a curved path or large acceleration over a short period of time?
To return to the same point, both accelerations should return the same time dilations, as far as the accelerations are concerned.
The time dilation relative to velocity alone may and likely would be different, since the velocity could remain equivalent between the two examples while the time changes.
Tach's response is correct, in either case. The example offered looks like the two paths are equivalent so all time dilations would also be equivalent.
Nothing to do with GR. Nothing to do with equivalence principle. Nothing to do with acceleration, the elapsed time is a function of velocity only, acceleration does not affect it. The simple answer, using SR , is that the proper times for the twins are:
$$\tau_A=\tau_B=\frac{2 \pi}{\omega} \sqrt{1-(\frac{\omega R}{c})^2}$$
1. You don't get to move the goalposts.
2. Try to learn a little physics:
$$\tau=\frac{2 \pi}{\omega} \sqrt{1-(\frac{\omega R}{c})^2}=\frac{2 \pi R}{v} \sqrt{1-(\frac{v}{c})^2}$$
3. Where is the "paradox"?
I concur, as this is a simplification of $$\tau = \int_A^B \sqrt{1 - \left( \frac{\vec{v}(\lambda)}{c} \right)^2} \frac{dt}{d\lambda} d\lambda$$ for the case that $$\left| \vec{v}(\lambda) \right| = v_0 = \omega R$$ and $$\int_A^B \frac{dt}{d\lambda} d\lambda = \frac{2 \pi R}{v_0} = \frac{2 \pi}{\omega}$$.
For one cycle each we have:
$$\tau_A = \frac{\pi \cdot 10 \, \textrm{a} \cdot c}{0.98 \, c} \sqrt{ 1 - \left( \frac{0.98 \, c}{c} \right)^2 } = \frac{500 \pi}{49} \times \frac { 3 \sqrt{11}}{50} \, \textrm{a} = \frac{ 30 \pi \sqrt{11}}{49} \, \textrm{a} \approx 6.4 \, \textrm{a} $$
$$\tau_B = \frac{\pi \cdot 20 \, \textrm{a} \cdot c}{0.49 \, c} \sqrt{ 1 - \left( \frac{0.49 \, c}{c} \right)^2 } = \frac{2000 \pi}{49} \times \frac {\sqrt{7599}}{100} \, \textrm{a} = \frac{ 20 \pi \sqrt{7599}}{49} \, \textrm{a} \approx 110 \, \textrm{a} $$
But it takes 4 cycles around A to catch up to the same position and time of 1 cycle around B, so compare:
$$4 \tau_A = \frac{ 120 \pi \sqrt{11}}{49} \, \textrm{a} < \frac{ 20 \pi \sqrt{7599}}{49} \, \textrm{a} = \tau_B$$.
So B, which travelled a path through space-time that was significantly closer to inertial motion than A, is about 86 years (annum = $$\textrm{a}$$) older than A when they meet again.
Try to understand a little physics. Physics is much more than SR.
I used a helper reference system that everyone understand the case.
But there are only two reference frames a and b.
In these reference frames the trajectory and the speed are changed. (must be translate)
But it is the responsibility the one who responds to the challenge, and say who is "old" and who is "young", a or b.
Emil, I agree. It looks like you are in the process of formulating a question, not a debate topic.
No -- there are two travelers, a and b. The only reference frame (coordinate system for space and time) used was that where the speed of the travelers and the diameters of their circular trajectories was described.
That is not a debate, that is asking a question.
It is clear that you are the one who doesn't.
Sure, but you are a denier of mainstream physics, obsessed with "refuting" relativity.
It has been explained to you. The fact that you don't understand doesn't come as a surprise.
Throwing pearls in front of .....
Try to understand. In the case presented by me are only two objects a and b and their corresponding reference systems.
It is not a question. It is a case with which I prove that the time paradox in SR is a real paradox.
All you have proven is your crass ignorance. Again.
Both rpenner and I responded giving you detailed, well documented scientific answers. The fact that you don't understand the answer is not our fault. Your crass ignorance and gross prejudice is at fault.
You need to compare $$\sqrt{7599}=87$$ and $$6 \sqrt{11}=19.8$$, so B is only 67 (a) older than A.
Hi everyone.
Like OnlyMe, I only wish to make an observation.
In other threads here, posters have distinguished the SR and the GR 'component contributions' to effects on orbiting satellite clocks/time etc.
Since these two 'components' CAN be distinguished, we then can just treat emil's scenario as two well separated EQUALLY MASSED gravitational bodies such that their respective gravity wells do not much affect the 'other one' of the two (a & b) orbiters (in equally periodic/shaped orbits) around their respective bodies, which respective orbits tangentially momentarily coincide as emil illustrated.
Now, if we separate the GR effects from the purely SR effects, since these two effects can apparently BE separated and allowed for accordingly, the scenario can be analyzed in that manner for the SR component effects only?
Just a suggestion. Cheers!
Like OnlyMe, I only wish to make an observation.
In other threads here, posters have distinguished the SR and the GR 'component contributions' to effects on orbiting satellite clocks/time etc.
Since these two 'components' CAN be distinguished, we then can just treat emil's scenario as two well separated EQUALLY MASSED gravitational bodies such that their respective gravity wells do not much affect the 'other one' of the two (a & b) orbiters (in equally periodic/shaped orbits) around their respective bodies, which respective orbits tangentially momentarily coincide as emil illustrated.
Now, if we separate the GR effects from the purely SR effects, since these two effects can apparently BE separated and allowed for accordingly, the scenario can be analyzed in that manner for the SR component effects only?
Just a suggestion. Cheers!
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