| Rationality: | irrational algebraic |
| Continued Fraction Linear: | [1;2,6,1,3,5,4,22,1,1,4,1,2,84,...] |
| Continued Fraction Periodic: | not periodic |
| Continued Fraction Finite: | infinite |
| Algebraic: | real root of |
In mathematics, the supergolden ratio is a geometrical proportion close to . Its true value is the real solution of the equation
The name supergolden ratio results from analogy with the golden ratio, the positive solution of the equation
Two quantities are in the supergolden ratio-squared if
\left(
| a+b | |
| a |
\right)2=
| a | |
| b |
| a+b | |
| a |
Based on this definition, one has
\begin{align} 1&=\left(
| a+b | |
| a |
\right)2
| b | |
| a |
\\ &=\left(
| a+b | |
| a |
\right)2\left(
| a+b | |
| a |
-1\right)\\ &\implies\psi2\left(\psi-1\right)=1\end{align}
\psi3-\psi2-1=0.
1.465571231876768...
The minimal polynomial for the reciprocal root is the depressed cubic
x3+x-1
w1,2=\left(1\pm
| 1 | |
| 3 |
\sqrt{
| 31 | |
| 3 |
1/\psi=\sqrt[3]{w1}+\sqrt[3]{w2}
1/\psi=
| 2 | |
| \sqrt{3 |
is the superstable fixed point of the iteration
x\gets(2x3+1)/(3x2+1)
The iteration
x\gets\sqrt[3]{1+x2
\psi=\sqrt[3]{1+\sqrt[3/2]{1+\sqrt[3/2]{1+ … }}}
Dividing the defining trinomial
x3-x2-1
x2+x/\psi2+1/\psi
x1,2=\left(-1\pmi\sqrt{4\psi2+3}\right)/2\psi2,
x1+x2=1-\psi
x1x2=1/\psi.
Many properties of are related to golden ratio . For example, the supergolden ratio can be expressed in terms of itself as the infinite geometric series
\psi=
| infty | |
| \sum | |
| n=0 |
\psi-3n
\psi2=
| infty | |
| 2\sum | |
| n=0 |
\psi-7n,
\varphi=
| infty | |
| \sum | |
| n=0 |
\varphi-2n
1+\varphi-1+\varphi-2=2
| 7 | |
| \sum | |
| n=0 |
\psi-n=3.
For every integer
n
\begin{align} \psin&=\psin-1+\psin-3\\ &=\psin-2+\psin-3+\psin-4\\ &=\psin-2+2\psin-4+\psin-6.\end{align}
Argument
\theta=\arcsec(2\psi4)
\tan(\theta)-4\sin(\theta)=3\sqrt{3}.
Continued fraction pattern of a few low powers
\psi-1=[0;1,2,6,1,3,5,4,22,...] ≈ 0.6823
\psi0=[1]
\psi1=[1;2,6,1,3,5,4,22,1,...] ≈ 1.4656
\psi2=[2;6,1,3,5,4,22,1,1,...] ≈ 2.1479
\psi3=[3;6,1,3,5,4,22,1,1,...] ≈ 3.1479
\psi4=[4;1,1,1,1,2,2,1,2,2,...] ≈ 4.6135
\psi5=[6;1,3,5,4,22,1,1,4,...] ≈ 6.7614
Notably, the continued fraction of begins as permutation of the first six natural numbers; the next term is equal to their
1/\sqrt{\psi}
\psi11=67.000222765... ≈ 67+1/4489
The minimal polynomial of the supergolden ratio
m(x)=x3-x2-1
\Delta=-31
K=Q(\sqrt{\Delta})
\tau=(1+\sqrt{\Delta})/2
\psi=
| e\piη(\tau) | |
| \sqrt{2 |
η(2\tau)}
Expressed in terms of the Weber-Ramanujan class invariant Gn
\psi=
| ak{f | |
| ( |
\sqrt{\Delta})}{\sqrt{2}}=
| G31 | |
| \sqrt[4]{2 |
}
Properties of the related Klein j-invariant result in near identity
e\pi
kr=λ*(r)
λ*(31)=\sin(\arcsin\left((\sqrt[4]{2}\psi)-12\right)/2)
Narayana's cows is a recurrence sequence originating from a problem proposed by the 14th century Indian mathematician Narayana Pandita. He asked for the number of cows and calves in a herd after 20 years, beginning with one cow in the first year, where each cow gives birth to one calf each year from the age of three onwards.
The Narayana sequence has a close connection to the Fibonacci and Padovan sequences and plays an important role in data coding, cryptography and combinatorics. The number of compositions of n into parts 1 and 3 is counted by the nth Narayana number.
The Narayana sequence is defined by the third-order recurrence relation
Nn=Nn-1+Nn-3
N0=N1=N2=1
The first few terms are 1, 1, 1, 2, 3, 4, 6, 9, 13, 19, 28, 41, 60, 88,... .The limit ratio between consecutive terms is the supergolden ratio.
The first 11 indices n for which
Nn
The sequence can be extended to negative indices using
Nn=Nn+3-Nn+2
The generating function of the Narayana sequence is given by
| 1 | |
| 1-x-x3 |
=
| infty | |
| \sum | |
| n=0 |
Nnxn
x<1/\psi
The Narayana numbers are related to sums of binomial coefficients by
Nn=
| \lfloorn/3\rfloor | |
| \sum | |
| k=0 |
{n-2k\choosek}
The characteristic equation of the recurrence is
x3-x2-1=0
Nn-2=a\alphan+b\betan+c\gamman
31x3+x-1=0
\left\vertb\betan+c\gamman\right\vert<1/\sqrt{\alphan
\alpha=\psi
a\psin+2
a=\psi/(\psi2+3)=
Coefficients
a=b=c=1
An=Nn+2Nn-3
The first few terms are 3, 1, 1, 4, 5, 6, 10, 15, 21, 31, 46, 67, 98, 144,... .
This anonymous sequence has the Fermat property: if p is prime,
Ap\equivA1\bmodp
n\mid(An-1)
Q=\begin{pmatrix}1&0&1\ 1&0&0\ 0&1&0\end{pmatrix},
The trace of gives the above .
Alternatively, can be interpreted as incidence matrix for a D0L Lindenmayer system on the alphabet with corresponding substitution rule
\begin{cases} a \mapsto ab\\ b \mapsto c\\ c \mapsto a \end{cases}
l(wn)=Nn.
Associated to this string rewriting process is a compact set composed of self-similar tiles called the Rauzy fractal, that visualizes the combinatorial information contained in a multiple-generation three-letter sequence.[5]
A supergolden rectangle is a rectangle whose side lengths are in a ratio. Compared to the golden rectangle, containing linear ratios
\varphi2:\varphi:1
Given a rectangle of height, length and diagonal length
\sqrt{\psi3
1+\psi2=\psi3
\psi2:1
\psi-1=\psi-2
1/\sqrt{\psi}
Numbering counter-clockwise starting from the upper right, the resulting first, second and fourth parts are all supergolden rectangles; while the third has aspect ratio
\psi3:1
\psi3:\psi2:\psi:1
\psi6:\psi4:\psi2:1
In the first part supergolden rectangle perpendicular to the original one, the process can be repeated at a scale of
1:\psi2
x3=x2+1
x2=x+1
x3=x+1
x3=2x2+1