metastable said:Suppose the planet is an oblate spheroid such that when it rotates it becomes a sphere through centrifugal forces
The triangle is specified to be loose. So, to my mind, the OP is describing the scenario where the triangle does not stretch and incorrectly describing Neil's observations.PeterDonis said:As the scenario is presented in the OP, it is inconsistent. The OP claims that Neil will see the triangle still match the dots, which implies that the triangle must stretch. But it also claims that Michael will see the triangle length contracted, which implies that the triangle does not stretch.
Either choice would be consistent by itself; but only one of the two can be true of a single scenario.
Actually I did not intent to “claim” the matching, but more assumed that it would match. From my previous question (Why is the null-result of M&M experiment considered as proof for RT) I learned (from Nugatory) that “the experiments are at rest relative to the apparatus, so they find no length contraction.”. Hence, I also assumed that the stretching of the dots would not take place in Neil’s perspective.PeterDonis said:As the scenario is presented in the OP, it is inconsistent. The OP claims that Neil will see the triangle still match the dots, which implies that the triangle must stretch. But it also claims that Michael will see the triangle length contracted, which implies that the triangle does not stretch.
Ibix said:it seemed to me you were entertaining the possibility that the loose triangle could stretch
I wouldn't call it an influence of a higher order. It's just that there is an awful lot of mass bound together and undergoing ferocious acceleration, and you can't neglect the effects of that by using an inertial frame (or any other way). In the Michelson-Morley case nothing is accelerating so there are no forces distorting anything.Foppe Hoekstra said:But as you try to tell me now, I should understand that here an influence of ‘higher’ order is involved.