Plastic ratio

 ( Cubic Irrational Numbers ) 

In mathematics, the plastic ratio is a geometrical aspect ratio, given by the unique real polynomial root of the equation Its decimal expansion begins with .

The adjective plastic does not refer to Plastic, but to the formative and sculptural qualities of this ratio, as in plastic arts.

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Definition Three quantities are in the plastic ratio if $$\backslash frac\{b\}\{c\}\; =\; \backslash frac\{a\}\{b\}\; =\; \backslash frac\{b+c\}\{a\}$$ This ratio is commonly denoted

Substituting $b=\backslash rho\; c\; \backslash ,$ and $a=\backslash rho\; b\; =\backslash rho^2\; c\; \backslash ,$ in the last fraction, $$\backslash rho\; =\backslash frac\{c(\backslash rho+1)\}\{\backslash rho^2\; c\}.$$ It follows that the plastic ratio is the unique real solution of the cubic equation $\backslash rho^3\; -\backslash rho\; -1\; =0.$

Solving with Cardano's formula, $$\backslash begin\{align\}$$

w_{1,2} &=\frac12 \left( 1 \pm \frac13 \sqrt{\frac{23}{3}} \right) \\
\rho &=\sqrt[3]{w_1} +\sqrt[3]{w_2} \end{align} 
     

or, using the hyperbolic cosine, $$\backslash rho\; =\backslash frac\{2\}\{\; \backslash sqrt\{3\}\}\; \backslash cosh\; \backslash left(\; \backslash frac\{1\}\{3\}\; \backslash operatorname\{arcosh\}\; \backslash left(\; \backslash frac\{3\; \backslash sqrt\{3\}\}\{2\}\; \backslash right)\; \backslash right).$$

is the superstable fixed point of the iteration $x\; \backslash gets\; (2x^3\; +1)\; /(3x^2\; -1)\; ,$ which is the update step of Newton's method applied to
     

The iteration $x\; \backslash gets\; \backslash sqrt\{1\; +\backslash tfrac\{1\}\{x\}\}$ results in the continued reciprocal square root $$\backslash rho\; =\backslash sqrt\{1\; +\backslash cfrac\{1\}\{\backslash sqrt\{1\; +\backslash cfrac\{1\}\{\backslash sqrt\{1\; +\backslash cfrac\{1\}\{\backslash ddots\}\}\}\}\}\}$$

Dividing the defining trinomial $x^3\; -x\; -1$ by one obtains $x^2\; +\backslash rho\; x\; +1\; /\backslash rho\; ,$ and the conjugate elements of are $$x\_\{1,2\}\; =\; \backslash frac12\; \backslash left(\; -\backslash rho\; \backslash pm\; i\; \backslash sqrt\{3\; \backslash rho^2\; -\; 4\}\; \backslash right),$$ with $x\_1\; +x\_2\; =-\backslash rho\; \backslash ;$ and $\backslash ;\; x\_1x\_2\; =1\; /\backslash rho.$

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Properties The plastic ratio and golden ratio are the only morphic numbers: real numbers for which there exist natural numbers m and n such that and Morphic numbers can serve as basis for a system of measure.

Properties of (m=3 and n=4) are related to those of (m=2 and n=1). For example, The plastic ratio satisfies the continued radical $$\backslash rho\; =\backslash sqrt3\{1\; +\backslash sqrt3\{1\; +\backslash sqrt3\{1\; +\backslash cdots\}\}\}\; ,$$ while the golden ratio satisfies the analogous $$\backslash varphi\; =\backslash sqrt\{1\; +\backslash sqrt\{1\; +\backslash sqrt\{1\; +\backslash cdots\}\}\}\; .$$

The plastic ratio can be expressed in terms of itself as the infinite geometric series $$\backslash begin\{align\}$$

\rho &=\sum_{n=0}^{\infty} \rho^{-5n} \\
\rho^2 &=\sum_{n=0}^{\infty} \rho^{-3n},\end{align}
     

in comparison to the golden ratio identity $$\backslash varphi\; =\backslash sum\_\{n=0\}^\{\backslash infty\}\; \backslash varphi^\{-2n\}\; \backslash text\{\; and\; \}\; vice~versa.$$ Additionally, $1\; +\backslash varphi^\{-1\}\; +\backslash varphi^\{-2\}\; =2\; ,$ while $\backslash sum\_\{n=0\}^\{13\}\; \backslash rho^\{-n\}\; =4.$

For every integer one has $$\backslash begin\{align\}$$

\rho^n &=\rho^{n-2} +\rho^{n-3}\\
&=\rho^{n-1} +\rho^{n-5}\\
&=\rho^{n-3} +\rho^{n-4} +\rho^{n-5}
     

\end{align} from this an infinite number of further relations can be found.

The algebraic solution of a reduced quintic equation can be written in terms of square roots, cube roots and the Bring radical. If $y\; =x^\{5\}\; +x$ then $x\; =\; BR(y).$ Since $\backslash rho^\{-5\}\; +\backslash rho^\{-1\}\; =1,\; \backslash ;\backslash rho\; =1\; /BR(1).$

Continued fraction pattern of a few low powers $$\backslash begin\{align\}$$

\rho^{-1} &= [0;1,3,12,1,1,3,2,3,2,...] \approx 0.7549 \;(\tfrac{25}{33}) \\
\rho^0 &= [1] \\
\rho^1 &= [1;3,12,1,1,3,2,3,2,4,...] \approx 1.3247 \;(\tfrac{45}{34}) \\
\rho^2 &= [1;1,3,12,1,1,3,2,3,2,...] \approx 1.7549 \;(\tfrac{58}{33}) \\
\rho^3 &= [2;3,12,1,1,3,2,3,2,4,...] \approx 2.3247 \;(\tfrac{79}{34}) \\
\rho^4 &= [3;12,1,1,3,2,3,2,4,2,...] \approx 3.0796 \;(\tfrac{40}{13}) \\
\rho^5 &= [4;12,1,1,3,2,3,2,4,2,...] \approx 4.0796 \;(\tfrac{53}{13})\,... \\
\rho^7 &= [7;6,3,1,1,4,1,1,2,1,1,...] \approx 7.1592 \;(\tfrac{93}{13})\,... \\
\rho^9 &= [12;1,1,3,2,3,2,4,2,141,...] \approx 12.5635 \;(\tfrac{88}{7})
     

\end{align}

The convergents of the continued fraction expansion of the plastic ratio are good rational approximations: $$\backslash tfrac\{4\}\{3\},\; \backslash tfrac\{49\}\{37\},\; \backslash tfrac\{53\}\{40\},\; \backslash tfrac\{102\}\{77\},\; \backslash tfrac\{257\}\{194\},\; \backslash tfrac\{359\}\{271\},\; \backslash tfrac\{820\}\{619\},\; \backslash tfrac\{2819\}\{2128\},\; \backslash tfrac\{6458\}\{4875\},\; \backslash tfrac\{28651\}\{21628\},\; \backslash tfrac\{63760\}\{48131\},\; \backslash ldots$$

The plastic ratio is the smallest Pisot number. By definition of these numbers, the absolute value $1\; /\backslash sqrt\{\backslash rho\}$ of the algebraic conjugates is smaller than 1, thus powers of generate . For example: $\backslash rho^\{29\}\; =3480.0002874...\; \backslash approx\; 3480\; +1/3479.$ After 29 rotation steps the phases of the inward spiraling conjugate pair – initially close to – nearly align with the imaginary axis.

The minimal polynomial of the plastic ratio $m(x)\; =x^3\; -x\; -1$ has discriminant $\backslash Delta=-23\; .$ The Hilbert class field of imaginary quadratic field $K\; =\; \backslash mathbb\{Q\}(\; \backslash sqrt\{\backslash Delta\})$ can be formed by adjoining . With argument $\backslash tau=(1\; +\backslash sqrt\{\backslash Delta\})/2\backslash ,$ a generator for the ring of integers of , one has the special value of Dedekind eta quotient  $$\backslash rho\; =\backslash frac\{\; e^\{\backslash pi\; i/24\}\backslash ,\backslash eta(\backslash tau)\}\{\; \backslash sqrt\{2\}\backslash ,\backslash eta(2\backslash tau)\}\; .$$

Expressed in terms of the Weber-Ramanujan class invariant G_n  $$\backslash rho\; =\backslash frac\{\; \backslash mathfrak\{f\}\; (\; \backslash sqrt\{\; \backslash Delta\}\; )\; \}\{\; \backslash sqrt\{2\}\; \}\; =\; \backslash frac\{\; G\_\{23\}\; \}\{\; \backslash sqrt4\{2\}\; \}.$$

Properties of the related Klein j-invariant result in near identity $e^\{\backslash pi\; \backslash sqrt\{-\; \backslash Delta\}\}\; \backslash approx\; \backslash left(\; \backslash sqrt\{2\}\backslash ,\backslash rho\; \backslash right)^\{24\}\; -\; 24\; .$ The difference is .

The elliptic integral singular value  $k\_\{r\}\; =\backslash lambda^\{*\}(r)$ for has closed form expression $$\backslash lambda^\{*\}(23)\; =\backslash sin\; (\; \backslash arcsin\; \backslash left(\; (\; \backslash sqrt4\{2\}\backslash ,\backslash rho)^\{-12\}\; \backslash right)\; /2)$$ (which is less than 1/3 the eccentricity of the orbit of Venus).

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Van der Laan sequence In his quest for perceptible clarity, the Dutch Benedictine monk and architect Dom Hans van der Laan (1904-1991) asked for the minimum difference between two sizes, so that we will clearly perceive them as distinct. Also, what is the maximum ratio of two sizes, so that we can still relate them and perceive nearness. According to his observations, the answers are , spanning a single order of size. Requiring proportional continuity, he constructed a geometric series of eight measures ( types of size) with common ratio Put in rational form, this architectonic system of measure is constructed from a subset of the numbers that bear his name.

The Van der Laan numbers have a close connection to the Perrin number and . In combinatorics, the number of compositions of n into parts 2 and 3 is counted by the nth Van der Laan number.

The Van der Laan sequence is defined by the third-order recurrence relation $$V\_n\; =V\_\{n-2\}\; +V\_\{n-3\}\; \backslash text\{\; for\; \}\; n\; >\; 2,$$ with initial values $$V\_1\; =0,\; V\_0\; =V\_2\; =1.$$

The first few terms are 1, 0, 1, 1, 1, 2, 2, 3, 4, 5, 7, 9, 12, 16, 21, 28, 37, 49, 65, 86,... . The limit ratio between consecutive terms is the plastic ratio:$\backslash lim\_\{n\backslash rightarrow\backslash infty\}\; V\_\{n+1\}/V\_n\; =\backslash rho.$

+ Table of the eight Van der Laan measures ! k !! n − m !! !! err !! interval

minor element

major element

minor piece

major piece

minor part

major part

minor whole

major whole

The first 14 indices n for which is prime are n = 5, 6, 7, 9, 10, 16, 21, 32, 39, 86, 130, 471, 668, 1264 . The last number has 154 decimal digits.

The sequence can be extended to negative indices using $$V\_n\; =V\_\{n+3\}\; -V\_\{n+1\}.$$

The generating function of the Van der Laan sequence is given by

The sequence is related to sums of binomial coefficients by $$V\_n\; =\backslash sum\_\{k\; =\backslash lfloor\; (n\; +2)/3\; \backslash rfloor\}^\{\backslash lfloor\; n\; /2\; \backslash rfloor\}\{k\; \backslash choose\; n\; -2k\}$$

The characteristic equation of the recurrence is $x^3\; -x\; -1\; =0.$ If the three solutions are real root and conjugate pair and , the Van der Laan numbers can be computed with the Binet formula $$V\_\{n-1\}\; =a\; \backslash alpha^n\; +b\; \backslash beta^n\; +c\; \backslash gamma^n\; ,$$ with real and conjugates and the roots of $23x^3\; +x\; -1\; =0.$

Since and $\backslash alpha\; =\backslash rho\; ,$ the number is the nearest integer to $a\backslash ,\backslash rho^\{n+1\}\; ,$ with and $a\; =\backslash rho\; /(3\; \backslash rho^2\; -1)\; =$

Coefficients $a\; =b\; =c\; =1$ result in the Binet formula for the related sequence $P\_n\; =2V\_n\; +V\_\{n-3\}\; .$

The first few terms are 3, 0, 2, 3, 2, 5, 5, 7, 10, 12, 17, 22, 29, 39, 51, 68, 90, 119,... .

This Perrin sequence has the Fermat property: if p is prime, $P\_\{p\}\; \backslash equiv\; P\_1\; \backslash bmod\; p\; .$ The converse does not hold, but the small number of $\backslash ,n\; \backslash mid\; P\_n$ makes the sequence special. The only 7 composite numbers below to pass the test are n = 521, 904631, 16532714, 24658561, 27422714, 27664033, 46672291.

The Van der Laan numbers are obtained as integral powers of a matrix with real eigenvalue

The trace of gives the Perrin numbers.

Alternatively, can be interpreted as incidence matrix for a D0L L-system on the alphabet with corresponding Semi-Thue system $$\backslash begin\{cases\}\; a\; \backslash ;\backslash mapsto\; \backslash ;b\; \backslash \backslash \; b\; \backslash ;\backslash mapsto\; \backslash ;ac\; \backslash \backslash \; c\; \backslash ;\backslash mapsto\; \backslash ;a\; \backslash end\{cases\}$$ and initiator . The series of words produced by iterating the substitution have the property that the number of and are equal to successive Van der Laan numbers. Their lengths are $l(w\_n)\; =V\_\{n+2\}.$

Associated to this string rewriting process is a set composed of three overlapping Self-similarity tiles called the Rauzy fractal, that visualizes the combinatorial information contained in a multiple-generation letter sequence.

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Geometry

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Partitioning the square There are precisely three ways of partitioning a square into three similar rectangles: Feedback in:

1. The trivial solution given by three congruent rectangles with aspect ratio 3:1.
2. The solution in which two of the three rectangles are congruent and the third one has twice the side lengths of the other two, where the rectangles have aspect ratio 3:2.
3. The solution in which the three rectangles are all of different sizes and where they have aspect ratio ρ². The ratios of the linear sizes of the three rectangles are: ρ (large:medium); ρ² (medium:small); and ρ³ (large:small). The internal, long edge of the largest rectangle (the square's fault line) divides two of the square's four edges into two segments each that stand to one another in the ratio ρ. The internal, coincident short edge of the medium rectangle and long edge of the small rectangle divides one of the square's other, two edges into two segments that stand to one another in the ratio ρ⁴.

The fact that a rectangle of aspect ratio ρ² can be used for dissections of a square into similar rectangles is equivalent to an algebraic property of the number ρ² related to the Routh–Hurwitz theorem: all of its conjugates have positive real part.

The circumradius of the snub icosidodecadodecahedron for unit edge length is  $$\backslash frac\{1\}\{2\}\; \backslash sqrt\{\; \backslash frac\{2\; \backslash rho\; -1\}\{\backslash rho\; -1\}\}.$$

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Cubic Lagrange interpolation The unique positive node that optimizes cubic Lagrange interpolation on the interval is equal to The square of is the single real root of polynomial $P(x)\; =25x^3\; +17x^2\; +2x\; -1$ with discriminant

(2025). 9781461463931 ISBN 9781461463931

Expressed in terms of the plastic ratio, $t\; =\backslash sqrt\{\backslash rho\}\; /(\backslash rho^2\; +1),$ which is verified by insertion into

With optimal node set $T\; =\backslash \{-1,-t,\; t,\; 1\backslash \},$ the Lebesgue function evaluates to the minimal cubic Lebesgue constant $\backslash Lambda\_3(T)\; =\; \backslash frac\{1\; +t^2\}\{1\; -t^2\}\backslash ,$ at critical point $x\_c\; =\backslash rho^2\; t.$

The constants are related through $x\_c\; +t\; =\backslash sqrt\{\backslash rho\}$ and can be expressed as infinite geometric series $$\backslash begin\{align\}$$

x_c &=\sum_{n=0}^{\infty} \sqrt{\rho^{-(8n +5)}} \\
t &=\sum_{n=0}^{\infty} \sqrt{\rho^{-(8n +9)}}.\end{align} 
     

Each term of the series corresponds to the diagonal length of a rectangle with edges in ratio which results from the relation $\backslash rho^n\; =\backslash rho^\{n-1\}\; +\backslash rho^\{n-5\},$ with odd. The diagram shows the sequences of rectangles with common shrink rate converge at a single point on the diagonal of a rho-squared rectangle with length $\backslash sqrt\{\backslash rho\; \backslash vphantom\{/\}\}\; =\backslash sqrt\{1\; +\backslash rho^\{-4\}\}.$

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Plastic pentagon A spiral of equilateral triangles with edges in ratio tiles a plastic pentagon with four angles of 120 and one of 60 degrees. The initial triangle is positioned at the left-hand side of a parallelogram with base to side ratio and left base angle 60 degrees, so that two edges of the triangle are collinear with sides of the parallelogram. Scaling the parallelogram in ratio accompanied with a clockwise rotation by 60 degrees, the horizontal base is mapped onto the third edge of the triangle. The centre of rotation is on the short (falling) diagonal, dividing it in ratio , the expansion rate for a half-turn. Iteration of the process traces an infinite, closed sequence of equilateral triangles with pentagonal boundary.

The logarithmic spiral through the vertices of all triangles has polar slope $k\; =\backslash frac\{3\}\{\backslash pi\}\; \backslash ln(\; \backslash rho).$ For parallelogram base , the length of the short diagonal is $\backslash sqrt\{\backslash rho^2\; -\; \backslash rho\; +\; 1\}$ with angle $\backslash arctan(\; \backslash tfrac\{\backslash sqrt\{3\}\}\{1\; -2\backslash rho\}).$ The length of the discrete spiral is $\backslash rho^5\; =\backslash sum\_\{n=0\}^\{\backslash infty\}\; \backslash rho^\{-n\};$ the pentagon has area $\backslash tfrac\{\backslash sqrt\{3\}\}\{4\}\; \backslash rho^3\; =\backslash tfrac\{\backslash sqrt\{3\}\}\{4\}\; \backslash sum\_\{n=0\}^\{\backslash infty\}\; \backslash rho^\{-2n\}.$

In the vector image, the construction is repeated on each side of a triangle. Rutherford Boyd discovered a related figure, build on the sides of the triangle.

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Plastic spiral A plastic spiral is a logarithmic spiral that gets wider by a factor of for every quarter turn. It is described by the polar equation $r(\; \backslash theta)\; =a\; \backslash exp(k\; \backslash theta),$ with initial radius and parameter $k\; =\backslash frac\{2\}\{\backslash pi\}\; \backslash ln(\; \backslash rho).$ If drawn on a rectangle with sides in ratio , the spiral has its pole at the foot of altitude of a triangle on the diagonal and passes through vertices of rectangles with aspect ratio which are perpendicularly aligned and successively scaled by a factor

In 1838 Henry Moseley noticed that whorls of a shell of the chambered nautilus are in geometrical progression: "It will be found that the distance of any two of its whorls measured upon a radius vector is one-third that of the next two whorls measured upon the same radius vector ... The curve is therefore a logarithmic spiral." Moseley thus gave the expansion rate $\backslash sqrt4\{3\}\; \backslash approx\; \backslash rho\; -1/116$ for a quarter turn. Considering the plastic ratio a three-dimensional equivalent of the ubiquitous golden ratio, it appears to be a natural candidate for measuring the shell.

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History and names

was first studied by [[Axel Thue]] in 1912 and by G. H. Hardy in 1919. French high school student  discovered the ratio for himself in 1924. In his correspon­dence with Hans van der Laan a few years later, he called it the radiant number (). Van der Laan initially referred to it as the fundamental ratio (), using the plastic number () from the 1950s onward. In 1944 Carl Siegel showed that  is the smallest possible Pisot–Vijayaraghavan number and suggested naming it in honour of Thue.
     

Unlike the names of the golden ratio and , the word plastic was not intended by van der Laan to refer to a specific substance, but rather in its adjectival sense, meaning something that can be given a three-dimensional shape. This, according to Richard Padovan, is because the characteristic ratios of the number, and , relate to the limits of human perception in relating one physical size to another. Van der Laan designed the 1967 St. Benedictusberg Abbey church to these plastic number proportions..

The plastic number is also sometimes called the silver number, a name given to it by Midhat J. Gazalé  and subsequently used by Martin Gardner, (Link to the 1994 Quantum article without Gardner's Postscript.) but that name is more commonly used for the silver ratio , one of the ratios from the family of first described by Vera W. de Spinadel. Gardner suggested referring to as "high phi", and Donald Knuth created a special typographic mark for this name, a variant of the Greek letter phi ("φ") with its central circle raised, resembling the Georgian letter pari ("Ⴔ").

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See also

• Solutions of equations similar to $x^3\; =x\; +1$:
• Golden ratio – the positive solution of the equation $x^2\; =x\; +1$
• Supergolden ratio – the real solution of the equation $x^3\; =x^2\; +1$

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Notes

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Further reading

• .
• .
• .

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External links

• Plastic rectangle and Padovan sequence at Tartapelago by Giorgio Pietrocola.
• The digital study room of Dom Hans van der Laan at The Van der Laan Archives.
• .

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