The dimensions of the Earth and Moon are in Phi relationship, forming a Triangle based on 1.618.

The illustration shows the relative sizes of the Earth and the Moon to scale.

Draw a radius of the Earth (1).

Draw a line from the center point of the Earth to the center point of the Moon (square root of Phi).

Draw a line to connect the two lines to form a Golden Triangle (Phi).

Using dimensions from Wikipedia and geometry’s classic Pythagorean Theorem, this is expressed mathematically as follows:

Dimension

(km) Proportion

(Earth=1) Mathematical

Expression Radius of Earth 6,378.10 1.000 A Radius of Moon 1,735.97 0.272 Earth + Moon 8,114.07 1.272 B Hypotenuse 10,320.77 1.618 (Φ) C, where C²=A²+B², so

C=√(A²+B²) Hypotenuse² /

(Earth Radius +

Moon Radius)² 1.618 (Φ) C²/B² Another way of looking at the relationship is to take 10320.77² / 8114.07², which is 106,518,293.39 / 65,838,131.96, which rounds to 1.618. The calculation to 6 significant digits is 1.61788…, which is different from 1.61803… by only 0.0009%. This triangle is known as a Kepler triangle. This geometric construction is the same as that which appears to have been used in the construction of the Great Pyramid of Egypt.

Source: Hidden Nature by Alick Bartholomew. Thanks to Sathimantha Malalasekera for bringing this to my attention.

Certain solar system orbital periods are closely related to phi

Mercury Venus Earth Jupiter Saturn Power of Phi -3 -1 0 5 7 Decimal Result 0.24 0.62 1.0 11.1 29.0 Actual Period 0.24 0.62 1.0 11.9 29.5

Saturn reveals a golden ratio phi relationship in several of its dimensions

Certain planets of our solar system seem to exhibit a relationship to phi, as shown by the following table of the time it takes to orbit around the Sun:

The diameter of Saturn is very close to a phi relationship with the diameter of its rings, as illustrated by the green lines. The inner ring division is in a relationship that is very close to phi with the diameter of the rings outside the sphere of the planet, as illustrated by the blue lines.The Cassini division in the rings of Saturn falls at the Golden Section of the width of the lighter outside section of the rings.

Note: Phi grid showing Golden Ratio lines provided by PhiMatrix software.

A closer look at Saturn’s rings reveals a darker inner ring which exhibits the same golden section proportion as the brighter outer ring.

Venus and Earth reveal a golden ratio phi relationship

Venus and the Earth are linked in an unusual relationship involving phi. Start by letting Mercury represent the basic unit of orbital distance and period in the solar system:

Planet Distance

from

the sun

in km (000) Distance

where

Mercury

equals 1 Period

where

Mercury

equals 1 Mercury 57,910 1.0000 1.0000 Venus 108,200 1.8684 2.5490 Earth 149,600 2.5833 4.1521

Curiously enough we find:

Ö Period of Venus * Phi = Distance of the Earth

Ö 2.5490 * 1.6180339 = 1.5966 * 1.6180339 = 2.5833

In addition, Venus orbits the Sun in 224.695 days while Earth orbits the Sun in 365.242 days, creating a ratio of 8/13 (both Fibonacci numbers) or 0.615 (roughly phi.) Thus 5 conjunctions of Earth and Venus occur every 8 orbits of the Earth around the Sun and every 13 orbits of Venus.

Mercury, on the other hand, orbits the Sun in 87.968 Earth days, creating a conjunction with the Earth every 115.88 days. Thus there are 365.24/115.88 conjunctions in a year, or 22 conjunctions in 7 years, which is very close to Pi!

See more relationships at the Solar Geometry site.

Relative planetary distances average to Phi

The average of the mean orbital distances of each successive planet in relation to the one before it approximates phi:

Planet Mean

distance

in million

kilometers

per NASA Relative

mean

distance

where

Mercury=1 Mercury 57.91 1.00000 Venus 108.21 1.86859 Earth 149.60 1.38250 Mars 227.92 1.52353 Ceres 413.79 1.81552 Jupiter 778.57 1.88154 Saturn 1,433.53 1.84123 Uranus 2,872.46 2.00377 Neptune 4,495.06 1.56488 Pluto 5,869.66 1.30580 Total 16.18736 Average 1.61874 Phi 1.61803 Degree of variance (0.00043)

Note: We sometimes forget about the asteroids when thinking of the planets in our solar system. Ceres, the largest asteroid, is nearly spherical, comprises over one-third the total mass of all the asteroids and is thus the best of these minor planets to represent the asteroid belt. (Insight on mean orbital distances contributed by Robert Bartlett.)

2005 unveiled the discovery of a 10th planet called 2003UB313. It was found at a distance of 97 times that of the Earth from the Sun. Its ratio to Pluto would thus be 2.47224, much higher than any previous planet to planet orbital distance ratio. Could it be that this is actually the 11th planet and the 10th planet will be found at an orbit whose ratio is 1.52793 times that of Pluto, preserving the phi average? Time will only tell, but if it happens remember that you heard it here first.

The shape of the Universe itself is a dodecahedron based on Phi

New findings in 2003 based on the study of data from NASA’s Wilkinson Microwave Anisotropy Probe (WMAP) on cosmic background radiation reveal that the universe is finite and shaped like a dodecahedron, a geometric shape based on pentagons, which are based on phi. See the Universe page for more.