The Coriolis force involves a rotating frame of reference: either the Earth is revolving around its own axis, or the ether drift is rotating above the surface of the Earth.
That is why the Coriolis force, gyrocompasses, Foucault's pendulum cannot be used to prove either geocentricity or heliocentricity.
The deciding factor is the GLOBAL SAGNAC EFFECT.
The fact that satellites DO NOT register/record either the orbital Coriolis effect or the rotational Sagnac effect has forced mainstream science to accept the local-aether model.
Mach's principle, Barbour-Bertotti experiment:
https://www.theflatearthsociety.org/forum/index.php?topic=30499.msg953747#msg953747Global Sagnac effect formula derivation (MGX, ring laser gyroscopes):
https://www.theflatearthsociety.org/forum/index.php?topic=30499.msg2117351#msg2117351Flat earth long distance artillery projectiles DePalma effect:
https://www.theflatearthsociety.org/forum/index.php?topic=30499.msg2029817#msg2029817https://www.theflatearthsociety.org/forum/index.php?topic=30499.msg2032069#msg2032069https://www.theflatearthsociety.org/forum/index.php?topic=30499.msg2106204#msg2106204Now, I am going to put an end to your presence here as a professional meteorologist.
Here is the
barometer pressure paradox.
"It has been known now for two and a half centuries, that there are more or less daily variations in the height of the barometer, culminating in two maxima and two minima during the course of 24 hours. The same observation has been made and puzzled over at every station at which pressure records were kept and studied, but without success in finding for it the complete physical explanation."
First, the correct station pressure data as it is measured all around the world.
First reference.
NATIONAL WEATHER SERVICE DATA:
The most basic change in pressure is the twice daily rise and fall in due to the heating from the sun. Each day, around 4 a.m./p.m. the pressure is at its lowest and near its peak around 10 a.m./p.m. The magnitude of the daily cycle is greatest near the equator decreasing toward the poles.
http://oceanservice.noaa.gov/education/yos/resource/JetStream/atmos/pressure.htmEach day, around 4 a.m./p.m. the pressure is at its lowest and near its peak around 10 a.m./p.m.
Second reference.
GRAPHS SHOWING THE DAILY SEMIDIURNAL BAROMETRIC PRESSURE CHANGES AT 10:00 AM/10:00 PM (MAXIMUMS) AND 4:00 PM/4:00 AM (MINIMUMS):
http://www.geografia.fflch.usp.br/graduacao/apoio/Apoio/Apoio_Elisa/flg0355/textos/Ahrens_cap9.pdf (PG. 211)
Third reference.
A remarkable characteristic of the semi-diurnal barometric variation is the regularity of the occurrence of the maxima and minima and their uniformity in time of day in all latitudes. While the amplitude of these waves may vary greatly with latitude, with elevation, and with location, whether over the sea or over the land, the local times of maxima and minima are very constant.
http://www.archive.org/stream/bulletinobserv06terruoft/bulletinobserv06terruoft_djvu.txt(Bulletin of Applied Physical Science)
A remarkable characteristic of the semi-diurnal barometric variation is the regularity of the occurrence of the maxima and minima and their uniformity in time of day in all latitudes.
ALL LATITUDES, no exception recorded.
EVER.
Fourth reference.
It has been known now for two and a half centuries, that there are more or less daily variations in the height of the barometer, culminating in two maxima and two minima during the course of 24 hours. The same observation has been made and puzzled over at every station at which pressure records were kept and studied, but without success in finding for it the complete physical explanation. In speaking of the diurnal and semidiurnal variations of the barometer, Lord Rayleigh says: ‘The relative magnitude of the latter [semidiurnal variations], as observed at most parts of the earth’s surface, is still a mystery, all the attempted explanations being illusory.
Fifth reference.
The atmospheric pressure is greatest at about 10:00 a.m. and 10:00 pm. and least at about 4:00 a.m. and 4:00 p.m. The variations are primarily the result of the combined effects of the sun's gravitational attraction and solar heating, with solar heating being the major component.
http://ufdc.ufl.edu/UF00001262/00001THIS REFERENCE EVEN HAS A GRAPH ATTACHED WHICH DOES SHOW THE 10:00 AM AND 10:00 PM MAXIMUMS (PAGE 569).
The best reference from Soil Engineering.
The atmospheric pressure is greatest at about 10:00 a.m. and 10:00 pm. and least at about 4:00 a.m. and 4:00 p.m.
Sixth reference.
The barometric pressure curve shows a portion of the normal twice-daily oscillation that occurs due to solar and lunar gravitational forces (atmospheric tides), with high pressures at approximately 10:00 AM and PM, and low pressures at 4:00 AM and PM.
http://info.ngwa.org/gwol/pdf/930158405.PDFSeventh reference.
http://www-das.uwyo.edu/~geerts/cwx/notes/chap01/diurnal.htmlSurface pressure measurements in Taiwan (at 25 deg. N) are least around 4am and (especially) 4 pm Local Standard Time, and most around (especially) 10am, and 10pm LST; the amplitude of the semidiurnal cycle is about 1.4 hPa.
Eighth reference.
http://books.google.ro/books?id=vNkZAQAAIAAJ&pg=RA1-PA217&lpg=RA1-PA217&dq=barometer+pressure+semidiurnal+change+10+am+4+pm&source=bl&ots=zgQHfJMC_w&sig=NMbmgLuqwPVwEfGVp3WuSu8Mdgg&hl=ro&sa=X&ei=-As4UqWRL4qp4ATI2ICIBA&ved=0CEAQ6AEwAQ#v=onepage&q=barometer%20pressure%20semidiurnal%20change%2010%20am%204%20pm&f=falseTHIS IS REAL SCIENCE: DAILY SEMIDIURNAL CHANGES IN THE BAROMETER PRESSURE READING.
Maximums at 10:00 am and 10:00 pm, and minimums at 4:00 am and 4:00 pm.
Ninth reference.
Humboldt carried a barometer with him on his famous South American journeys of 1799-1804. In his book Cosmos he remarked that the two daily maxima at about 10 a.m. and 10 p.m. were so regular that his barometer could serve somewhat as a clock.
http://www-eaps.mit.edu/faculty/lindzen/29_Atmos_Tides.pdfU.S. Weather Bureau, “Ten-Year Normals of Pressure Tendencies and Hourly Station Pressures for the United States,”
Technical Paper No. 1, Washington, D.C. 1943.
Semidiurnal variations: maximums at 10:00 am/10:00 pm and minimums at 4:00 pm/4:00 am
Surface pressure exhibits a remarkably stable semidiurnal oscillation with maxima at 10 a.m. and 10 p.m. and minima at 4 a.m. and 4 p.m. local time. This semidiurnal oscillation in surface pressure is a universal phenomenon observed worldwide and can be identified even in disturbed weather conditions.
http://amselvam.webs.com/SEN1/bio2met.htmNATIONAL WEATHER SERVICE DATA:
The most basic change in pressure is the twice daily rise and fall in due to the heating from the sun. Each day, around 4 a.m./p.m. the pressure is at its lowest and near its peak around 10 a.m./p.m.
A remarkable characteristic of the semi-diurnal barometric variation is the regularity of the occurrence of the maxima and minima and their uniformity in time of day in all latitudes. (Bulletin of Applied Physical Science)
ALL LATITUDES, no exception recorded.
Surface pressure exhibits a remarkably stable semidiurnal oscillation with maxima at 10 a.m. and 10 p.m. and minima at 4 a.m. and 4 p.m. local time. This semidiurnal oscillation in surface pressure is a universal phenomenon observed worldwide and can be identified even in disturbed weather conditions.
BAROMETER PRESSURE PARADOXOne maximum is at 10 a.m., the other at 10 p.m.; the two minima are at 4 a.m. and 4 p.m.
The heating effect of the sun can explain neither the time when the maxima appear nor the time of the minima of these semidiurnal variations.
If the pressure becomes lower without the air becoming lighter through a lateral expansion due to heat, this must mean that the same mass of air gravitates with changing force at different hours.Lord Rayleigh: ‘The relative magnitude of the latter [semidiurnal variations], as observed at most parts of the earth’s surface, is still a mystery, all the attempted explanations being illusory.’
Currently, the barometer pressure paradox CANNOT BE EXPLAINED AT ALL.
Richard Lindzen tried, some 40 years ago, to include the effects of ozone and water absorption in the atmospheric tide equations; notwithstanding that in his original paper he did express some doubts, the scientific community happily concluded that the barometer pressure paradox has been solved.
Not by a long shot.
Here is S.J. Woolnough's paper detailing the gross error/omission made by Lindzen.
https://journals.ametsoc.org/doi/full/10.1175/JAS3290.1While the surface pressure signal of the simulated atmospheric tides in the model agree well with both theory and observations in their magnitude and phase, sensitivity experiments suggest that the role of the stratospheric ozone in forcing the semidiurnal tide is much reduced compared to theoretical predictions. Furthermore, the influence of the cloud radiative effects seems small. It is suggested that the radiative heating profile in the troposphere, associated primarily with the water vapor distribution, is more important than previously thought for driving the semidiurnal tide.