I'm talking about a tidally locked two body system with perfectly circular orbits, where you continuously send signals from a fixed point on one surface to a fixed point on the other surface. The frequency shift would be constant here.PeterDonis said:
Actually, I need to correct this. The ##g_{tt}## coefficient will not include the ##v^2 / c^2## term, since that is not a property of the geometry or the choice of coordinates. That term comes from the ##\sqrt{1 - v^2 / c^2}## SR time dilation. The fact that all the corrections are small compared to ##1## is what allows the ##v^2 / c^2## term to come under the square root in the first formula.PeterDonis said:
If you have a planet of radius R and mass M orbiting another planet of radius R and mass M (technically, the berycenter) the clocks run at the same rate. The cancellation is perfect. If the bodies have different masses and/or radii, the cancellation is only approximate. In the Earth-Moon case, it's abour 2/3.PeterDonis said:
Relative to each other, yes.Vanadium 50 said:
As you describe it here, it wouldn't in the Earth-Moon case at present (see the second paragraph of the post of mine that you quoted). If the Earth were fully tidally locked to the Moon (i.e., its rotation had slowed to the same period as the Moon's orbit), then yes.A.T. said:
Yes, that's what I meant. Or just sent the signal from the pole.PeterDonis said:
May I ask about bold selected quote.DanMP said:
The "ticking differently on the lunar surface than from orbit" seems to be key. We are not talking about clocks at rest on an equipotential surface.Gleb1964 said:
Thank you for your answers!PeterDonis said:
DanMP said:
, relative to infinity, their clock rate, assuming we are still within the domain of validity of the weak field, slow motion approximation, will be only the effect of their potentials.DanMP said:
Yes, something like that. But I also suggest to send signals between clocks, all this time, in order to monitor the progress. I would send one signal from the Moon clock at every 12 hours and record the exact time of arrival at the Earth clock/clocks. If, from the Earth clock, a reply signal is sent instantly, we may approximate the signal travel time and make a prety good progress chart.PeterDonis said:
So in your mind's eye, you have a Earth tidally locked to the moon and vice versa. You assume approximate long term stability, ignoring any gravitational radiation that may be slowing the assembly down over the very long term. You exchange time-stamped radio signals periodically and observe a drift between the local clock and the received remote clock readings. Your peer at the remote clock sees an inverse drift. This, even before the drift reaches a point where the clocks are out of synchronization by more than one round trip time.DanMP said:
Doing this requires adopting a simultaneity convention. But there is no common simultaneity convention that is "natural" for both clocks, since they are in relative motion. And the obvious simplest simultaneity convention to adopt, that of the barycentric inertial frame, is not "natural" for either clock, since both clocks are moving in this frame.DanMP said:
Ok, it's not easy, nor accurate, but this signals exchange may still be useful to monitor the divergence of the clocks. The final, more accurate, result would be available when the moon clock returns.PeterDonis said:
They won't be using the same simultaneity convention as the Earth-based GPS system does. And their rates will be adjusted from their "natural" rates just as Earth-based GPS satellite clock rates are--but adjusted to a different standard.DanMP said:
I'm interested in much more than this particular subject (as you can see from my threads/posts), even in other time measurement scenarios, but now/here I'm interested in this planet-moon scenario.Vanadium 50 said:
you can open dedicated threads. I don't mind.
It is enough, as Hafele-Keating experiment proved.Vanadium 50 said:
Probably, but even so, if there is a discrepancy between theory and reality, the clocks on the Moon would diverge from the clocks on the Earth more than expected. Over time this divergence would increase/accumulate and we would notice it, eventually.PeterDonis said:
Why would the discrepancy between theory and reality be more noticeable with clocks on the moon than with different pairs of clocks on the earth? That makes no sense whatsoever.DanMP said:
If there were such a divergence we would already have seen it, in errors in the GPS system, for example. As has already been pointed out, the Moon's orbital speed is just not that fast, comparatively speaking.DanMP said:
Yes, which means that experiments we have already done are sufficient to test for any kind of divergence between theory and reality that the experiments you are proposing would test for. So the experiments you are proposing do not push the boundaries of our testing of theory against reality at all.DanMP said:
Yes.DanMP said:
What discrepancy? I wrote "if" bolded (if):Dale said:
and I wrote the above in order to point that even when the moon-based clockDanMP said:
we still can use them to prove/disprove the theory.PeterDonis said:
You seem to be missing the point by a considerable margin.DanMP said:
In terms of proving the theory, that ship has sailed. The theory is well accepted. The tick rate of clocks in the neighborhood of the moon is expected to follow the predictions of general relativity.DanMP said:
Prove in the sense of providing yet more confirming data to add to the mountain of confirming data we already have, yes. But not in the sense of pushing the boundaries of the domain in which we've confirmed the theory; as I've already said, your proposed experiments do not do that at all.DanMP said: