The discussion centers on the synchronization of clocks in a two-story building under the influence of gravity, specifically addressing gravitational time dilation. Participants confirm that while initial synchronization is possible, ongoing synchronization is not feasible due to the effects of gravity and relative motion, as evidenced by experiments like the Pound-Rebka experiment. The GPS system exemplifies this principle, as it requires regular corrections to account for time dilation effects caused by gravity and relative velocity. The conversation also highlights the importance of defining "synchronization" in both special and general relativity contexts.
PREREQUISITESPhysicists, engineers, and students interested in relativity, timekeeping technology, and the practical applications of gravitational effects on time synchronization.
actionintegral said:My friend and I are in a two story building. I am on the lower floor, he is on the upper. We are in a constant gravitational field.
Is it true that our watches cannot be synchronized? If so, what is the proof of this claim?
lalbatros said:Just one more short comment.
the GPS system is always re-synchronising all the atomic clocks in the system
This experiment has been performed many, many times: http://www.upscale.utoronto.ca/GeneralInterest/Key/relgen.htmactionintegral said:My friend and I are in a two story building. I am on the lower floor, he is on the upper. We are in a constant gravitational field.
Is it true that our watches cannot be synchronized? If so, what is the proof of this claim?
A) In 1959 Pound and Rebka placed an atomic clock at the top of a seven storey office building at Harvard University and compared its frequency with that of a similar clock placed in the basement. Using an effect named after the German physicist, Mossbauer, they confirmed the prediction of General Relativity to within 1%. More recent experiments along these lines have improved the precision to 0.02%.
Chris Hillman said:Hi, all,
I sense some confusion here between an "initial synchronization" and keeping clocks at different locations (perhaps in a curved spacetime, and/or undergoing acceleration), which are exchaning time signals, running at carefully adjusted rates so that they continue to remain "in synch" over a substantial period of time.
The signals are time signals. So all the GPS receiver has to do is compare them to each other.lalbatros said:It is very nice that you provide us with good references.
Till now I was never able to undestand how my pocket GPS gets its position. Would you have a clear text on this topic? My problem was with how the receiver becomes able to detect the time delays needed for the positioning.
Might be a nitpick, but they aren't so much a regular correction as simply making the clocks tick at a different rate.Now, for the GPS system, it is clear that the clocks are drifting rather regularly under the effect of gravity. Therefore a regular correction is enough, as long as other perturbations are negligible.
It is critical. And to answer your various questions on the definition, it can be defined pretty much however you want, as long as you define it clearly. You pick a frame of reference and a method that arrives at a useful synchronization scheme.This leads me to a further question: how much is "synchronisation" a useful concept in general relativity?
True - all they really need to do is compare them several times to see how they are changing relative to each other.The two guys introduced by actionintegral can observe each other's laboratories without synchronizing their clocks. Synchonising clocks does not seem important to me in this context. It was only necessary for Special Relativity where this synchronisation is always possible in an inertial frame and where it leads to the relativity between inertial frames.