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This article analyses the LIGO (Laser Interferometer Gravitational-Wave Observatory). LIGO will make history, due to the fact that it’s completely failed to detect GWs (Gravitational Waves), and besides that won a Nobel Prize in 2017.
As happened, with the failure of the famous Michelson Interferometer, to detect the luminous Ether, that open the doors, for Einstein’s Theories of Relativity, the LIGO's failure, to detect true GWs, will certainly open doors, for the emergence of new physics models, at list the ones that can explain who make a True GWs Detector, as the Witte Ulianov Time Interferometer model.
To carry out this analysis, of one True Gravitational Waves Detector (TGWD), we will have the support of an Artificial Intelligence. But to do this we first need to show that today, the question is no longer using the TT (Turing Test) to distinguish between a person and an AI. This test has been improved, by the author, to be a new TTT (True Turing Test), and now allows us to differentiate a TAI (True Artificial Intelligence) from a FAI (Fake Artificial Intelligence).
This paper also introduces the Witte Ulianov Time Interferometer (WUTI), that can be used as base to make a TGWD. Built upon Einstein’s General Relativity (GR), WUTI capitalizes on the concept that gravitational fields can influence time dilation, akin to a "time flow rate". So, the WUTI identifies GWs through time
distortion, over two time sources, when these waves traverse the detector.
WUTI employs the Witte effect, first noted by R. D. Witte in 1991, while measuring disparities between atomic clocks. This effect enables the measurement of "time flow" alterations between two points in space, utilizing accurate time sources like atomic clocks or highly stable frequency laser sources. Upon encountering a gravitational wave, these clocks experience modified "time flow" between them, observable through phase comparators.
As a result, the WUTI detector operates without low-frequency limitations, capable of detecting gravitational waves, with periods ranging from seconds to hours. This enables the detection of slow gravitational field variations, facilitating the observation of Earth's field fluctuations due to its movement and rotation. The WUTI model can be used, with verry low costs, to improve the LIGO o a new Time Interferometer (LIGO-TI), able it to be a TGWD and finally detect true GWs.
WUTI model is easy to test because it can also observe gravitational fields of the moon, sun, and Milky Way, uncovering not just the gravitational waves, but also the "Gravity Ocean", on which the Starship Earth sails.
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