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That's indeed nonsense: You have to define acceleration against what. Otherwise your results are completely meaningless. Of course we cannot discuss this in detail if you don't give the details about your accelerometer.
vanhees71 said:There is also not a unique inertial reference frame. That's why we think about Galilei transformations which tell us how to convert the coordinates wrt. to one inertial frame to another. Of course there's also always (at least locally) a diffeomorphism between the observables as measured in one (inertial or accelerated) to any other (inertial or accelerated) frame of reference.
How about a really cheap one, that only gives the magnitude of proper acceleration. Do we need a reference frame for that? What about a thermometer?vanhees71 said:Of course we cannot discuss this in detail if you don't give the details about your accelerometer.
I guess, we should end this discussion, because it's obvious that I cannot make my point clear.Dale said:Therefore even for inertial devices my above argument holds. You cannot have simultaneously ##Frame_A=Objects_X## and ##Frame_B=Objects_X## and ##Frame_A\ne Frame_B##. It is a logical impossibility. The only resolution that is consistent with the math and the principle of relativity is ##Frame \ne Objects##
You mean the physical objects used to define a reference frame? Since these objects could be almost anything, I would just name the objects used.vanhees71 said:So how else would you call a "reference frame"?
I can easily talk about physics while using the word "clock" to refer to clocks and the word "rod" to refer to rods, and the word "reference frame" to refer to any of the many corresponding mathematical objects that could derived from the measurements of clocks and rods.vanhees71 said:Then you cannot talk about physics in general,
I am taking a reading from an instrument. That reading is an invariant fact of the matter that will hold regardless of what reference frame is used. One does not need a reference frame to read a number from an instrument. Nor does one need a specific reference frame in order to compute an invariant quantity.vanhees71 said:That's indeed nonsense: You have to define acceleration against what. Otherwise your results are completely meaningless. Of course we cannot discuss this in detail if you don't give the details about your accelerometer.
I have no idea why you think there is a problem in using different words for abstract concepts and the physical objects that are used for measurements, which can be related to those abstract concepts.vanhees71 said:Then you cannot talk about physics in general, and that's what theoretical physics is about.
No, they are two different experiments. Each experiment can be analyzed using an infinite number of reference framesvanhees71 said:No, your accelerometer will show a different reading whether you hold it fixed relative to the Earth or let it fall. These are two different reference frames.
This violates the principle of relativity. The principle of relativity specifically says that you can use any frame for analyzing an experiment. It does not require you to use a specific frame. According to relativity you are indeed free to use both ##Frame_A## and ##Frame_B## to describe the exact same ##Objects_X##vanhees71 said:Of course two different reference frames from which you observe the same "events" consist of two different measurement apparati which realize these two different reference frames. In your language in #77: If FrameA≠FrameB you have FrameA=ObjectsX and FrameB=ObjectsY.