Electromagnetic Acceleration

The theory of the Electromagnetic Accelerator (EA) states that there is a mechanism to the universe that pulls, pushes, or deflects light upwards. All light curves upwards over very long distances. The Electromagnetic Accelerator has been adopted as a modern alternative to the perspective theory proposed in Earth Not a Globe.

Sunrise and sunset happen as result of these upwardly curving light rays.



The above illustration depicts rays from the sun which intersect with the earth. Other rays not depicted may miss the earth and make a "u-turn" back into space.

It is believed that the bending of light does not simulate or match the globe curvature. Instead, the bending occurs more gradually over a greater distance. This is why observers can see further than they should in the classic Flat Earth water convexity experiments that take place on shorter ranges near sea level, and why the dip of the horizon at higher altitudes over longer ranges sits higher than the globe earth prediction but lower than a planar prediction (See: Evidence for Electromagnetic Acceleration).

=Mechanism=

One may point out that it would be quite unreasonable to assert that a particle or wave in motion would travel forever through the universe in a perfectly straight line, unperturbed by any of the variety of forces or phenomena which fills existence. Get into a car and attempt to drive in a perfectly straight line down a highway without turning the steering wheel left or right. It is a near impossible thing to do. The car is affected by the slope and texture of the terrain, alignment of your wheels, the wind, &c. An apparently straight heading turns into a curved one. When it comes to bullets, airplanes, et all, it is expected that bodies never realistically travel straightly. Straight line trajectories rarely, if ever, occur in nature.

While the mechanism which affects light over long distances is not known, the cosmological theme of upwards acceleration fits in with this Flat Earth model.

Articles of Interest

 * Light Bends Itself Around Corners - Physicsworld.com
 * Stanford Researchers Use Synthetic Magnetism to Control Light

=Terrestrial=

Clouds Lit From Underside
Rays which miss the earth will turn back up into space, and may hit the underside of clouds before sunrise or after sunset, giving them a reddish glow.



Horizon Dip
The Electromagnetic Accelerator predicts that at high altitudes where one can see further into the distance, the horizon will dip below eye level. Light which travels parallel from the limits of vision will be pulled upwards and miss the eye of the observer. The rays the observer will see are those rays which are transmitted at a lower angle and pulled upwards to meet the observer, resulting in a horizon which is slightly below eye level.



=Celestial=

Nearside Always Seen
A consequence of this paradigm of upwardly bending light is that the observer will always see the nearside (underside) of the celestial bodies. The below image depicts the extremes of the Moon's rising and setting. The image of the nearside face of the moon is bent upwards around the moon and faces the observers to either side of it.



Lunar Phases
When one observes the phases of the Moon they are seeing the Moon's day and night, a shadow created from the sun illuminating half of the spherical moon at any one time. As depicted in the previous section, due to EA we are always observing the nearside (or underside) of the moon.

The curved rays of the sun results in the phases upon the Moon's surface. The plane of the Moon's route is at an inclination to the plane of the Sun's ecliptic, with its highest side opposite from the sun. When the Moon is far from the Sun and higher than it, the Full Moon occurs. When the Moon is closer to the Sun and lower than it, the New Moon occurs1. The Moon moves at a slightly slower rate than the Sun across the sky, causing the range of phases. The time between two Full Moons, or between successive occurrences of the same phase, is about 29.53 days (29 days, 12 hours, 44 minutes) on average.



Sample large-scale sun ray diagram (side view):



Moon Position Table
Compare the above with the following table from Cornell University (Archive), which provides a rule-of-thumb summation for when the Moon rises and sets during its phases:

1 Around the time of the New Moon the Moon is not technically seen. According to Kean University (Archive):

Questions and Answers
Q: Does this model of the phases predict anything that RET does not?

A: According to the above rule-of-thumb table from Cornell University during the phases between New Moon and 1st Quarter (Half Moon) the Moon will not set in the sky until a time between Sunset (New) and Local Midnight (1st Quarter), meaning that the range of Crescent Moon phases will be seen during the night. In the Flat Earth Moon Phase diagrams above we can see how this can be possible -- of the nine phase examples arranged in a circle, it takes about two 'sections' for the celestial bodies to set from an overhead position. The Crescent Moon will overlap into the night time.

However, according to the geometric model of the phases in RET, a Crescent Moon appearing in the sky into late hours of the night is difficult to explain with the Round Earth model.

John Savage at Savage Plane explains the matter in an article and a video here:

Impossible Heliocentric Moon Phases Explained - Savage Plane (Archive)

The authors of the article even identify some dates in 2019 for when the Crescent Moon is seen past midnight for locations in the Northern Hemisphere -- which may be possible in the above Flat Earth model since locations in the Northern Hemisphere are closer to the center, but hard to explain with the Round Earth schema where those locations are geometrically pointing away from the daylight side. A gibbous moon seen during the day is another issue, essentially the reverse of the above, and is also discussed.

=See Also=


 * Evidence for Electromagnetic Acceleration
 * Sunrise and Sunset
 * The Equinox
 * Magnification of the Sun at Sunset