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The Lunar Eclipse

From The Flat Earth Wiki

A Lunar Eclipse occurs about twice a year when a satellite of the sun passes between the sun and moon.

This satellite is called the Shadow Object or Antimoon. Its orbital plane is tilted at an angle to the sun's orbital plane, making eclipses possible only when the three bodies (Sun, Object, and Moon) are aligned. Within a given year, considering the orbitals of these celestial bodies, a maximum of three lunar eclipses can occur. Despite the fact that there are more solar than lunar eclipses each year, over time many more lunar eclipses are seen at any single location on earth than solar eclipses. This occurs because a lunar eclipse can be seen from the entire half of the earth beneath the moon at that time, while a solar eclipse is visible only along a narrow path on the earth's surface.

Total lunar eclipses come in clusters. There can be two or three during a period of a year or a year and a half, followed by a lull of two or three years before another round begins. When you add partial eclipses there can be three in a calendar year and again, it's quite possible to have none at all.

The shadow object is never seen in the sky because it orbits close to the sun. As the sun's powerful vertical rays hit the atmosphere during the day they will scatter and blot out nearly every single star and celestial body in the sky. We are never given a glimpse of the celestial bodies which appear near the sun during the day - they are completely washed out by the sun's light.

Dr. Samuel Birley Rowbotham has provided equations for finding the time, magnitude, and duration of a Lunar Eclipse at the end of Chapter 11 of Earth Not a Globe.

There is also a possibility that the Shadow Object is a known celestial body which orbits the sun; but more study would be needed to track the positions of Mercury, Venus and the sun's asteroid satellites and correlate them with the equations for the lunar eclipse before any conclusion could be drawn.

Ancient and modern astronomers

As far as the Lunar Eclipse goes, there is no evidence that the shadow which manifests on the moon during a Lunar Eclipse originates from the earth at all. That shadow could come from any celestial body intersecting the light between the sun and moon.

The only reason the Greeks and ancients (and modern astronomers) are able to predict the Lunar Eclipses was because the predictions are based on recurring charts and tables of past eclipses. It had nothing to do with the shape of the earth or the actual geometry of the cosmos. The Lunar Eclipse is a phenomenon which comes in patterns. By studying these patterns it is possible to predict when the next transit or eclipse will occur. The astronomer can use historic charts and tables with a few equations to predict the time, magnitude, and duration of a future eclipse.

This does not apply only to the eclipse, either: All recurring phenomena such as the transits of planets, occultations of bodies, and precision of paths across the sky are predicable only because they are phenomena which come in patterns. Astronomers predict celestial events by studying the patterns and predicting when the next occurrence will occur.

Modern Eclipse Models

Q. But what about NASA's yearly lunar eclipse predictions? They must be based on a geometric model, and not simply cycles in the sky, surely?

A. NASA freely admits that they use ancient cycle charts for their eclipse predictions. The Saros Cycle and those cobby old ancient methods which simply look at past patterns in the sky to predict the next one is precisely how "modern theorists" predict the lunar eclipse today.

See: Astronomical Prediction Based on Patterns - The Eclipses

Why the Lunar Eclipse is Red

The Lunar Eclipse is red because the light of the sun is shining through the edges of the Shadow Object which passes between the sun and moon during a Lunar Eclipse. The red tint occurs because the outer layers of the Shadow Object are not sufficiently dense. The Sun's light is powerful enough to shine through the outer layers of the Shadow Object, just as a flashlight is powerful enough to shine through your hand when you put it right up against your palm.

350x

The globular earth is said have a circumference of 24,900 miles while the atmosphere is said to extend only 100 miles around it. If the RE model were true, and the redness of the shadow was caused by the sun's light filtering through the earths atmosphere, then the earth's shadow upon the moon would only have a slight sliver of red around the shadow's edges. The moon could not turn entirely red as it does in the above animation. The fact that the moon turns entirely red during a Lunar Eclipse suggests that the light of the sun is flowing through the majority of the body which intersects the path of light. Clearly an impossibility in the RE explanation.

Lunar Eclipse Length

An interesting quote is fount in "Fifty Scientific Facts" (1896) by E. Breach:

  “ It is supposed that an eclipse of the moon is caused by the earth intervening between the sun and moon. The earth is reckoned to travel 1,100 miles per minute; how long would it be passing the moon, travelling herself at 180 miles per minute [or 1280 miles per minute if we include the speed of the earth]? Not four minutes. Yet the last eclipse of the moon, on February 28th, lasted 4 1/2 hours; so it could not be the earth intervening, as both luminaries were above the horizon when the eclipse commenced, and the spots of the moon could be seen distinctly through the shadow; the moon was also seen among the stars. ”

According to timeanddate.com on the length of the Lunar Eclipse for January 20–21, 2019 we read:

  “ "The total duration of the eclipse is 5 hours, 12 minutes. The total duration of the partial phases is 2 hours, 15 minutes. The duration of the full eclipse is 1 hour, 2 minutes." ”

On the subject of the Total Lunar Eclipse, timeanddate.com says:

  “ A total lunar eclipse usually happens within a few hours. Totality can range anywhere from a few seconds to about 100 minutes. The July 26, 1953 total lunar eclipse had one of the longest periods of totality in the 20th century—100 minutes and 43 seconds. ”

According to Ohio State University:

  “ The Earth's umbra is ~1.4 Million km long:

About 3.7x the mean Earth-Moon distance. Umbra's width is 9000 km at the distance of the Moon, or ~2.6x the Moon's diameter. ”

9000km converted to miles is 5592.341 miles
5592.341 miles / 180 miles per minute = 31.068 minutes to cross. Yet, as we read above, the Total Lunar Eclipse can last far longer.

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