|
Distances of the Planets from the Sun,
traditionally and using Solar Geometry
| Measuring the solar system by the Earth is wrong! |
All traditional charts of solar system distances are based on the measure of the
Earth's distance from the Sun, known as one Astronomical Unit. Distances of the
planets are thus shown as follows:
| Planet |
Distance
from
the sun
in km (000)
per NASA |
Distance
in AU
per NASA |
| Mercury |
57,910 |
0.3871 |
| Venus |
108,200 |
0.7233 |
| Earth |
149,600 |
1.0000 |
Mars |
227,940 |
1.5237 |
| Jupiter |
778,330 |
5.2034 |
(Note: The linked page at NASA shows more decimal points,
but calculated results are only accurate to the number of decimal places in the values
used, which in this case is the distance in kilometers.)
| Mercury should be used as the base measuring unit |
If you instead base solar system measurements on the distance of Mercury from the Sun,
you get these measures:
| Planet |
Distance
from
the sun
in km (000) |
Distance
where
Mercury
equals 1 |
| Mercury |
57,910 |
1.0000 |
| Venus |
108,200 |
1.8684 |
| Earth |
149,600 |
2.5833 |
| Mars |
227,940 |
3.9361 |
| Jupiter |
778,330 |
13.4403 |
| Only then can the planetary relationships
be seen |
It's a simple change, but this new view unveils an incredible insight into the
relationships among the planets. Each of these distance measures can be represented
with an elegant pattern of simple integers from 1 to 6 appearing in roots, multipliers and
exponents:
| Mercury = 1 = ½ (Ö1+1) |
| Mercury at aphelion = ½ ( Ö2 + 1 ) |
| Venus = Mercury * (½ ( Ö3 + 1 )) ² |
| Earth = Venus ¾ * (½ ( Ö5 + 1 )) |
| Mars = Earth ¾ * (½ ( Ö6 +
Ö2
)) |
| Jupiter = Mars * ( Ö2 + 2 ) |
Note: Öx indicates the
square root of x
| The
accumulation shows the distance of each from the Sun |
The distance of each planet from the Sun, using Mercury as 1, can thus
be represented as an accumulation of these relationships. An
alternate representation of the same number is used for Venus to Earth to add insight to the interesting
pattern that develops:
| Mercury= ½(Ö1+1) |
| Venus = (½(Ö3+1)) ² |
| Earth = ((½(Ö3+1))^(½(Ö4+1))*(½(Ö5+1))) |
| Mars = ((½(Ö3+1))^(½(Ö4+1))*(½(Ö5+1)))^¾*(½(Ö6+Ö2)) |
| Jupiter =(((½(Ö3+1))^(½(Ö4+1))*(½(Ö5+1)))^¾*(½(Ö6+Ö2)))*(Ö2+2) |
| The results are amazingly accurate |
The distances calculated by these formulas are almost identical to the relative
distances published by NASA:
| Planet |
Published
distance
from the
sun in km
(000) |
Relative
distance
from Sun,
where
Mercury=1 |
Alan
Bennett's
calculated
value per
above |
Degree
of
Variance |
| Mercury |
57,910 |
1.0000 |
1.0000 |
0.0000 |
| Venus |
108,200 |
1.8684 |
1.8660 |
0.0013 |
| Earth |
149,600 |
2.5833 |
2.5833 |
0.0000 |
| Mars |
227,940 |
3.9361 |
3.9365 |
-0.0001 |
| Jupiter |
778,330 |
13.4403 |
13.4399 |
0.0000 |
| But this is just the beginning of the incredible relationships that
result |
I am the Root and the Offspring of David, and the bright
Morning Star."
(Revelations 22:16)
|
