| Golden ratio | ||||
| Image Alt: | two line segments of lengths a and b in the golden ratio: a + b is to a as a is to b | |||
| Decimal: | ... | |||
| Continued Fraction: | 1+\cfrac{1}{1+\cfrac{1}{1+\cfrac{1}{1+\ddots}}} | |||
| Algebraic: |
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In mathematics, two quantities are in the golden ratio if their ratio is the same as the ratio of their sum to the larger of the two quantities. Expressed algebraically, for quantities
a
b
a>b>0
a
b
where the Greek letter phi (or
\phi
\varphi
\varphi2=\varphi+1
The golden ratio was called the extreme and mean ratio by Euclid, and the divine proportion by Luca Pacioli, and also goes by several other names.
Mathematicians have studied the golden ratio's properties since antiquity. It is the ratio of a regular pentagon's diagonal to its side and thus appears in the construction of the dodecahedron and icosahedron. A golden rectangle—that is, a rectangle with an aspect ratio of
\varphi
Some 20th-century artists and architects, including Le Corbusier and Salvador Dalí, have proportioned their works to approximate the golden ratio, believing it to be aesthetically pleasing. These uses often appear in the form of a golden rectangle.
Two quantities
a
b
\varphi
One method for finding a closed form for
\varphi
b/a=1/\varphi
Therefore,
Multiplying by
\varphi
The quadratic formula yields two solutions:
Because
\varphi
\varphi
| - | 1 |
| \varphi |
See also: Mathematics and art.
According to Mario Livio,
Ancient Greek mathematicians first studied the golden ratio because of its frequent appearance in geometry; the division of a line into "extreme and mean ratio" (the golden section) is important in the geometry of regular pentagrams and pentagons. According to one story, 5th-century BC mathematician Hippasus discovered that the golden ratio was neither a whole number nor a fraction (it is irrational), surprising Pythagoreans. Euclid's Elements provides several propositions and their proofs employing the golden ratio, and contains its first known definition which proceeds as follows:
The golden ratio was studied peripherally over the next millennium. Abu Kamil (c. 850–930) employed it in his geometric calculations of pentagons and decagons; his writings influenced that of Fibonacci (Leonardo of Pisa) (c. 1170–1250), who used the ratio in related geometry problems but did not observe that it was connected to the Fibonacci numbers.
Luca Pacioli named his book Divina proportione (1509) after the ratio; the book, largely plagiarized from Piero della Francesca, explored its properties including its appearance in some of the Platonic solids. Leonardo da Vinci, who illustrated Pacioli's book, called the ratio the sectio aurea ('golden section'). Though it is often said that Pacioli advocated the golden ratio's application to yield pleasing, harmonious proportions, Livio points out that the interpretation has been traced to an error in 1799, and that Pacioli actually advocated the Vitruvian system of rational proportions. Pacioli also saw Catholic religious significance in the ratio, which led to his work's title. 16th-century mathematicians such as Rafael Bombelli solved geometric problems using the ratio.
German mathematician Simon Jacob (d. 1564) noted that consecutive Fibonacci numbers converge to the golden ratio; this was rediscovered by Johannes Kepler in 1608. The first known decimal approximation of the (inverse) golden ratio was stated as "about
0.6180340
Eighteenth-century mathematicians Abraham de Moivre, Nicolaus I Bernoulli, and Leonhard Euler used a golden ratio-based formula which finds the value of a Fibonacci number based on its placement in the sequence; in 1843, this was rediscovered by Jacques Philippe Marie Binet, for whom it was named "Binet's formula". Martin Ohm first used the German term goldener Schnitt ('golden section') to describe the ratio in 1835. James Sully used the equivalent English term in 1875.
By 1910, inventor Mark Barr began using the Greek letter phi as a symbol for the golden ratio. It has also been represented by tau the first letter of the ancient Greek τομή ('cut' or 'section').
The zome construction system, developed by Steve Baer in the late 1960s, is based on the symmetry system of the icosahedron/dodecahedron, and uses the golden ratio ubiquitously. Between 1973 and 1974, Roger Penrose developed Penrose tiling, a pattern related to the golden ratio both in the ratio of areas of its two rhombic tiles and in their relative frequency within the pattern. This gained in interest after Dan Shechtman's Nobel-winning 1982 discovery of quasicrystals with icosahedral symmetry, which were soon afterward explained through analogies to the Penrose tiling.
The golden ratio is an irrational number. Below are two short proofs of irrationality:
This is a proof by infinite descent. Recall that:
If we call the whole
n
m,
To say that the golden ratio
\varphi
\varphi
n/m
n
m
n/m
n
m
n/m
m/(n-m)
\varphi
Another short proof – perhaps more commonly known – of the irrationality of the golden ratio makes use of the closure of rational numbers under addition and multiplication. If
\varphi=\tfrac12(1+\sqrt5)
2\varphi-1=\sqrt5
The golden ratio is also an algebraic number and even an algebraic integer. It has minimal polynomial
This quadratic polynomial has two roots,
\varphi
-\varphi-1.
The golden ratio is also closely related to the polynomial
which has roots
-\varphi
\varphi-1.
The conjugate root to the minimal polynomial
x2-x-1
The absolute value of this quantity corresponds to the length ratio taken in reverse order (shorter segment length over longer segment length,
b/a
This illustrates the unique property of the golden ratio among positive numbers, that
or its inverse:
The conjugate and the defining quadratic polynomial relationship lead to decimal values that have their fractional part in common with
\varphi
The sequence of powers of
\varphi
0.618033\ldots,
1.0,
1.618033\ldots,
2.618033\ldots;
\varphi
As a result, one can easily decompose any power of
\varphi
\varphi
\varphi
If
\lfloorn/2-1\rfloor=m,
The formula
\varphi=1+1/\varphi
It is in fact the simplest form of a continued fraction, alongside its reciprocal form:
The convergents of these continued fractions
2/1,
3/2,
5/3,
8/5,
13/8,
1/1,
1/2,
2/3,
3/5,
5/8,
\xi
p/q
This means that the constant
\left|\xi- p \right|< q
1 \sqrt{5 q2}.
\sqrt{5}
A continued square root form for
\varphi
\varphi2=1+\varphi
Fibonacci numbers and Lucas numbers have an intricate relationship with the golden ratio. In the Fibonacci sequence, each number is equal to the sum of the preceding two, starting with the base sequence
0,1
The sequence of Lucas numbers (not to be confused with the generalized Lucas sequences, of which this is part) is like the Fibonacci sequence, in which each term is the sum of the previous two, however instead starts with
2,1
Exceptionally, the golden ratio is equal to the limit of the ratios of successive terms in the Fibonacci sequence and sequence of Lucas numbers:
In other words, if a Fibonacci and Lucas number is divided by its immediate predecessor in the sequence, the quotient approximates
\varphi
For example,
| F16 | |
| F15 |
=
| 987 | |
| 610 |
=1.6180327\ldots,
| L16 | |
| L15 |
=
| 2207 | |
| 1364 |
=1.6180351\ldots.
These approximations are alternately lower and higher than
\varphi,
\varphi
Closed-form expressions for the Fibonacci and Lucas sequences that involve the golden ratio are:
Combining both formulas above, one obtains a formula for
\varphin
Between Fibonacci and Lucas numbers one can deduce
L2n=5
| 2 | |
| F | |
| n |
+2(-1)n=
| 2 | |
| L | |
| n |
-2(-1)n,
\vertLn-\sqrt{5}Fn\vert=
| 2 | |
| \varphin |
\to0,
(L3n/2)2=5(F3n/2)2+(-1)n.
These values describe
\varphi
Q(\sqrt5)
Successive powers of the golden ratio obey the Fibonacci recurrence, i.e.
\varphin+1=\varphin+\varphin-1.
The reduction to a linear expression can be accomplished in one step by using:
This identity allows any polynomial in
\varphi
Consecutive Fibonacci numbers can also be used to obtain a similar formula for the golden ratio, here by infinite summation:
In particular, the powers of
\varphi
\varphi0
\varphi
and so forth. The Lucas numbers also directly generate powers of the golden ratio; for
n\ge2
Rooted in their interconnecting relationship with the golden ratio is the notion that the sum of third consecutive Fibonacci numbers equals a Lucas number, that is
Ln=Fn-1+Fn+1
Ln=
| F2n | |
| Fn |
Both the Fibonacci sequence and the sequence of Lucas numbers can be used to generate approximate forms of the golden spiral (which is a special form of a logarithmic spiral) using quarter-circles with radii from these sequences, differing only slightly from the true golden logarithmic spiral. Fibonacci spiral is generally the term used for spirals that approximate golden spirals using Fibonacci number-sequenced squares and quarter-circles.
The golden ratio features prominently in geometry. For example, it is intrinsically involved in the internal symmetry of the pentagon, and extends to form part of the coordinates of the vertices of a regular dodecahedron, as well as those of a 5-cell. It features in the Kepler triangle and Penrose tilings too, as well as in various other polytopes.
Dividing by interior division
AB,
BC
B,
BC
AB.
AC.
C
BC.
AC
D.
A
AD.
AB
S.
S
AB
AS
SB
Dividing by exterior division
AS
S
SC
AS
AS.
AS
M.
M
MC
B
A
S
AS
AS
SB
Both of the above displayed different algorithms produce geometric constructions that determine two aligned line segments where the ratio of the longer one to the shorter one is the golden ratio.
See main article: Golden angle. When two angles that make a full circle have measures in the golden ratio, the smaller is called the golden angle, with measure
This angle occurs in patterns of plant growth as the optimal spacing of leaf shoots around plant stems so that successive leaves do not block sunlight from the leaves below them.
In a regular pentagon the ratio of a diagonal to a side is the golden ratio, while intersecting diagonals section each other in the golden ratio. The golden ratio properties of a regular pentagon can be confirmed by applying Ptolemy's theorem to the quadrilateral formed by removing one of its vertices. If the quadrilateral's long edge and diagonals are
a,
b,
a2=b2+ab.
ab
The diagonal segments of a pentagon form a pentagram, or five-pointed star polygon, whose geometry is quintessentially described by
\varphi
\varphi,
Pentagonal and pentagrammic geometry permits us to calculate the following values for
\varphi
See main article: Golden triangle (mathematics). The triangle formed by two diagonals and a side of a regular pentagon is called a golden triangle or sublime triangle. It is an acute isosceles triangle with apex angle 36° and base angles 72°. Its two equal sides are in the golden ratio to its base. The triangle formed by two sides and a diagonal of a regular pentagon is called a golden gnomon. It is an obtuse isosceles triangle with apex angle 108° and base angle 36°. Its base is in the golden ratio to its two equal sides. The pentagon can thus be subdivided into two golden gnomons and a central golden triangle. The five points of a regular pentagram are golden triangles, as are the ten triangles formed by connecting the vertices of a regular decagon to its center point.
Bisecting one of the base angles of the golden triangle subdivides it into a smaller golden triangle and a golden gnomon. Analogously, any acute isosceles triangle can be subdivided into a similar triangle and an obtuse isosceles triangle, but the golden triangle is the only one for which this subdivision is made by the angle bisector, because it is the only isosceles triangle whose base angle is twice its apex angle. The angle bisector of the golden triangle subdivides the side that it meets in the golden ratio, and the areas of the two subdivided pieces are also in the golden ratio.
If the apex angle of the golden gnomon is trisected, the trisector again subdivides it into a smaller golden gnomon and a golden triangle. The trisector subdivides the base in the golden ratio, and the two pieces have areas in the golden ratio. Analogously, any obtuse triangle can be subdivided into a similar triangle and an acute isosceles triangle, but the golden gnomon is the only one for which this subdivision is made by the angle trisector, because it is the only isosceles triangle whose apex angle is three times its base angle.
See main article: Penrose tiling. The golden ratio appears prominently in the Penrose tiling, a family of aperiodic tilings of the plane developed by Roger Penrose, inspired by Johannes Kepler's remark that pentagrams, decagons, and other shapes could fill gaps that pentagonal shapes alone leave when tiled together. Several variations of this tiling have been studied, all of whose prototiles exhibit the golden ratio:
1:\varphi
George Odom found a construction for
\varphi
See main article: Kepler triangle. The Kepler triangle, named after Johannes Kepler, is the unique right triangle with sides in geometric progression:These side lengths are the three Pythagorean means of the two numbers
\varphi\pm1
1n{:}\varphin{:}\varphi2
Among isosceles triangles, the ratio of inradius to side length is maximized for the triangle formed by two reflected copies of the Kepler triangle, sharing the longer of their two legs. The same isosceles triangle maximizes the ratio of the radius of a semicircle on its base to its perimeter.
For a Kepler triangle with smallest side length
s
See main article: Golden rectangle.
The golden ratio proportions the adjacent side lengths of a golden rectangle in
1:\varphi
\varphi
See main article: Golden rhombus. A golden rhombus is a rhombus whose diagonals are in proportion to the golden ratio, most commonly
1:\varphi
The lengths of its short and long diagonals
d
D
a
Its area, in terms of
a
d
Its inradius, in terms of side
a
Golden rhombi form the faces of the rhombic triacontahedron, the two golden rhombohedra, the Bilinski dodecahedron, and the rhombic hexecontahedron.
See main article: Golden spiral. Logarithmic spirals are self-similar spirals where distances covered per turn are in geometric progression. A logarithmic spiral whose radius increases by a factor of the golden ratio for each quarter-turn is called the golden spiral. These spirals can be approximated by quarter-circles that grow by the golden ratio, or their approximations generated from Fibonacci numbers, often depicted inscribed within a spiraling pattern of squares growing in the same ratio. The exact logarithmic spiral form of the golden spiral can be described by the polar equation with
(r,\theta)
Not all logarithmic spirals are connected to the golden ratio, and not all spirals that are connected to the golden ratio are the same shape as the golden spiral. For instance, a different logarithmic spiral, encasing a nested sequence of golden isosceles triangles, grows by the golden ratio for each 108° that it turns, instead of the 90° turning angle of the golden spiral. Another variation, called the "better golden spiral", grows by the golden ratio for each half-turn, rather than each quarter-turn.
The regular dodecahedron and its dual polyhedron the icosahedron are Platonic solids whose dimensions are related to the golden ratio. A dodecahedron has
12
20
30
For a dodecahedron of side
a
ru,
ri,
rm,
While for an icosahedron of side
a
The volume and surface area of the dodecahedron can be expressed in terms of
\varphi
As well as for the icosahedron:
These geometric values can be calculated from their Cartesian coordinates, which also can be given using formulas involving
\varphi
Sets of three golden rectangles intersect perpendicularly inside dodecahedra and icosahedra, forming Borromean rings. In dodecahedra, pairs of opposing vertices in golden rectangles meet the centers of pentagonal faces, and in icosahedra, they meet at its vertices. In all, the three golden rectangles contain
12
12
A cube can be inscribed in a regular dodecahedron, with some of the diagonals of the pentagonal faces of the dodecahedron serving as the cube's edges; therefore, the edge lengths are in the golden ratio. The cube's volume is
\tfrac{2}{2+\varphi}
\varphi:\varphi2
12
12
Other polyhedra are related to the dodecahedron and icosahedron or their symmetries, and therefore have corresponding relations to the golden ratio. These include the compound of five cubes, compound of five octahedra, compound of five tetrahedra, the compound of ten tetrahedra, rhombic triacontahedron, icosidodecahedron, truncated icosahedron, truncated dodecahedron, and rhombicosidodecahedron, rhombic enneacontahedron, and Kepler-Poinsot polyhedra, and rhombic hexecontahedron. In four dimensions, the dodecahedron and icosahedron appear as faces of the 120-cell and 600-cell, which again have dimensions related to the golden ratio.
The golden ratio's decimal expansion can be calculated via root-finding methods, such as Newton's method or Halley's method, on the equation
x2-x-1=0
x2-5=0
\sqrt{5}
n
O(M(n))
M(n)
n
\pi
e
F25001
F25000,
5000
10{,}000
\varphi
z=e2\pi
z5=1
z+\barz,
This also holds for the remaining tenth roots of unity satisfying
z10=1,
\Gamma
\Gamma(z-1)=\Gamma(z+1)
z=\varphi
z=-\varphi-1
When the golden ratio is used as the base of a numeral system (see golden ratio base, sometimes dubbed phinary or
\varphi
Z[\varphi]
a+b\varphi
a,b\inZ
The golden ratio also appears in hyperbolic geometry, as the maximum distance from a point on one side of an ideal triangle to the closer of the other two sides: this distance, the side length of the equilateral triangle formed by the points of tangency of a circle inscribed within the ideal triangle, is
4log(\varphi).
The golden ratio appears in the theory of modular functions as well. For
\left|q\right|<1
\operatorname{Im}\tau>0
(ez)1/5
ez/5
\tau\mapstoR(e2\pi)
\Gamma(5)
a,b\inR+
ab=\pi2,
\varphi
The Swiss architect Le Corbusier, famous for his contributions to the modern international style, centered his design philosophy on systems of harmony and proportion. Le Corbusier's faith in the mathematical order of the universe was closely bound to the golden ratio and the Fibonacci series, which he described as "rhythms apparent to the eye and clear in their relations with one another. And these rhythms are at the very root of human activities. They resound in man by an organic inevitability, the same fine inevitability which causes the tracing out of the Golden Section by children, old men, savages and the learned."
Le Corbusier explicitly used the golden ratio in his Modulor system for the scale of architectural proportion. He saw this system as a continuation of the long tradition of Vitruvius, Leonardo da Vinci's "Vitruvian Man", the work of Leon Battista Alberti, and others who used the proportions of the human body to improve the appearance and function of architecture.
In addition to the golden ratio, Le Corbusier based the system on human measurements, Fibonacci numbers, and the double unit. He took suggestion of the golden ratio in human proportions to an extreme: he sectioned his model human body's height at the navel with the two sections in golden ratio, then subdivided those sections in golden ratio at the knees and throat; he used these golden ratio proportions in the Modulor system. Le Corbusier's 1927 Villa Stein in Garches exemplified the Modulor system's application. The villa's rectangular ground plan, elevation, and inner structure closely approximate golden rectangles.
Another Swiss architect, Mario Botta, bases many of his designs on geometric figures. Several private houses he designed in Switzerland are composed of squares and circles, cubes and cylinders. In a house he designed in Origlio, the golden ratio is the proportion between the central section and the side sections of the house.
Leonardo da Vinci's illustrations of polyhedra in Pacioli's Divina proportione have led some to speculate that he incorporated the golden ratio in his paintings. But the suggestion that his Mona Lisa, for example, employs golden ratio proportions, is not supported by Leonardo's own writings. Similarly, although Leonardo's Vitruvian Man is often shown in connection with the golden ratio, the proportions of the figure do not actually match it, and the text only mentions whole number ratios.
Salvador Dalí, influenced by the works of Matila Ghyka, explicitly used the golden ratio in his masterpiece, The Sacrament of the Last Supper. The dimensions of the canvas are a golden rectangle. A huge dodecahedron, in perspective so that edges appear in golden ratio to one another, is suspended above and behind Jesus and dominates the composition.
A statistical study on 565 works of art of different great painters, performed in 1999, found that these artists had not used the golden ratio in the size of their canvases. The study concluded that the average ratio of the two sides of the paintings studied is
1.34,
1.04
1.46
\sqrt5
\sqrt2,
3,
4,
6.
See main article: Canons of page construction.
According to Jan Tschichold,
There was a time when deviations from the truly beautiful page proportions2n{:}3,
and the Golden Section were rare. Many books produced between 1550 and 1770 show these proportions exactly, to within half a millimeter.1n{:}\sqrt3,
According to some sources, the golden ratio is used in everyday design, for example in the proportions of playing cards, postcards, posters, light switch plates, and widescreen televisions.
The aspect ratio (width to height ratio) of the flag of Togo was intended to be the golden ratio, according to its designer.[1]
Ernő Lendvai analyzes Béla Bartók's works as being based on two opposing systems, that of the golden ratio and the acoustic scale, though other music scholars reject that analysis. French composer Erik Satie used the golden ratio in several of his pieces, including Sonneries de la Rose+Croix. The golden ratio is also apparent in the organization of the sections in the music of Debussy's Reflets dans l'eau (Reflections in Water), from Images (1st series, 1905), in which "the sequence of keys is marked out by the intervals and and the main climax sits at the phi position".
The musicologist Roy Howat has observed that the formal boundaries of Debussy's La Mer correspond exactly to the golden section. Trezise finds the intrinsic evidence "remarkable", but cautions that no written or reported evidence suggests that Debussy consciously sought such proportions.
Music theorists including Hans Zender and Heinz Bohlen have experimented with the 833 cents scale, a musical scale based on using the golden ratio as its fundamental musical interval. When measured in cents, a logarithmic scale for musical intervals, the golden ratio is approximately 833.09 cents.
See main article: Patterns in nature.
Johannes Kepler wrote that "the image of man and woman stems from the divine proportion. In my opinion, the propagation of plants and the progenitive acts of animals are in the same ratio".
The psychologist Adolf Zeising noted that the golden ratio appeared in phyllotaxis and argued from these patterns in nature that the golden ratio was a universal law. Zeising wrote in 1854 of a universal orthogenetic law of "striving for beauty and completeness in the realms of both nature and art".
However, some have argued that many apparent manifestations of the golden ratio in nature, especially in regard to animal dimensions, are fictitious.
The quasi-one-dimensional Ising ferromagnet
There is no known general algorithm to arrange a given number of nodes evenly on a sphere, for any of several definitions of even distribution (see, for example, Thomson problem or Tammes problem). However, a useful approximation results from dividing the sphere into parallel bands of equal surface area and placing one node in each band at longitudes spaced by a golden section of the circle, i.e.
360\circ/\varphi ≈ 222.5\circ.
The golden ratio is a critical element to golden-section search as well.
Examples of disputed observations of the golden ratio include the following:
1.45.
The Great Pyramid of Giza (also known as the Pyramid of Cheops or Khufu) has been analyzed by pyramidologists as having a doubled Kepler triangle as its cross-section. If this theory were true, the golden ratio would describe the ratio of distances from the midpoint of one of the sides of the pyramid to its apex, and from the same midpoint to the center of the pyramid's base. However, imprecision in measurement caused in part by the removal of the outer surface of the pyramid makes it impossible to distinguish this theory from other numerical theories of the proportions of the pyramid, based on pi or on whole-number ratios. The consensus of modern scholars is that this pyramid's proportions are not based on the golden ratio, because such a basis would be inconsistent both with what is known about Egyptian mathematics from the time of construction of the pyramid, and with Egyptian theories of architecture and proportion used in their other works.
The Parthenon's façade (c. 432 BC) as well as elements of its façade and elsewhere are said by some to be circumscribed by golden rectangles. Other scholars deny that the Greeks had any aesthetic association with golden ratio. For example, Keith Devlin says, "Certainly, the oft repeated assertion that the Parthenon in Athens is based on the golden ratio is not supported by actual measurements. In fact, the entire story about the Greeks and golden ratio seems to be without foundation." Midhat J. Gazalé affirms that "It was not until Euclid ... that the golden ratio's mathematical properties were studied."
From measurements of 15 temples, 18 monumental tombs, 8 sarcophagi, and 58 grave stelae from the fifth century BC to the second century AD, one researcher concluded that the golden ratio was totally absent from Greek architecture of the classical fifth century BC, and almost absent during the following six centuries.Later sources like Vitruvius (first century BC) exclusively discuss proportions that can be expressed in whole numbers, i.e. commensurate as opposed to irrational proportions.
The Section d'Or ('Golden Section') was a collective of painters, sculptors, poets and critics associated with Cubism and Orphism. Active from 1911 to around 1914, they adopted the name both to highlight that Cubism represented the continuation of a grand tradition, rather than being an isolated movement, and in homage to the mathematical harmony associated with Georges Seurat. (Several authors have claimed that Seurat employed the golden ratio in his paintings, but Seurat's writings and paintings suggest that he employed simple whole-number ratios and any approximation of the golden ratio was coincidental.) The Cubists observed in its harmonies, geometric structuring of motion and form, "the primacy of idea over nature", "an absolute scientific clarity of conception". However, despite this general interest in mathematical harmony, whether the paintings featured in the celebrated 1912 Salon de la Section d'Or exhibition used the golden ratio in any compositions is more difficult to determine. Livio, for example, claims that they did not, and Marcel Duchamp said as much in an interview. On the other hand, an analysis suggests that Juan Gris made use of the golden ratio in composing works that were likely, but not definitively, shown at the exhibition. Art historian Daniel Robbins has argued that in addition to referencing the mathematical term, the exhibition's name also refers to the earlier Bandeaux d'Or group, with which Albert Gleizes and other former members of the Abbaye de Créteil had been involved.
Piet Mondrian has been said to have used the golden section extensively in his geometrical paintings, though other experts (including critic Yve-Alain Bois) have discredited these claims.