Spiral of Theodorus

The spiral of Theodorus up to the triangle with a hypotenuse of √17

In geometry, the spiral of Theodorus (also called square root spiral, Einstein spiral or Pythagorean spiral)^[1] is a spiral composed of contiguous right triangles. It was first constructed by Theodorus of Cyrene.

Construction

The spiral is started with an isosceles right triangle, with each leg having unit length. Another right triangle is formed, an automedian right triangle with one leg being the hypotenuse of the prior triangle (with length √2) and the other leg having length of 1; the length of the hypotenuse of this second triangle is √3. The process then repeats; the i th triangle in the sequence is a right triangle with side lengths √i and 1, and with hypotenuse √i + 1. For example, the 16th triangle has sides measuring 4 (=√16), 1 and hypotenuse of √17

History and uses

Although all of Theodorus' work has been lost, Plato put Theodorus into his dialogue Theaetetus, which tells of his work. It is assumed that Theodorus had proved that all of the square roots of non-square integers from 3 to 17 are irrational by means of the Spiral of Theodorus.^[2]

Plato does not attribute the irrationality of the square root of 2 to Theodorus, because it was well known before him. Theodorus and Theaetetus split the rational numbers and irrational numbers into different categories.^[3]

Hypotenuse

Each of the triangles' hypotenuses h_i gives the square root of the corresponding natural number, with h₁ = √2.

Plato, tutored by Theodorus, questioned why Theodorus stopped at √17. The reason is commonly believed to be that the √17 hypotenuse belongs to the last triangle that does not overlap the figure.^[4]

Overlapping

In 1958, Erich Teuffel proved that no two hypotenuses will ever coincide, regardless of how far the spiral is continued. Also, if the sides of unit length are extended into a line, they will never pass through any of the other vertices of the total figure.^[4]^[5]

Extension

Colored extended spiral of Theodorus with 110 triangles

Theodorus stopped his spiral at the triangle with a hypotenuse of √17. If the spiral is continued to infinitely many triangles, many more interesting characteristics are found.

Growth rate

Angle

If φ_n is the angle of the nth triangle (or spiral segment), then:

\tan \left(\varphi _{n}\right)={\frac {1}{\sqrt {n}}}.

Therefore, the growth of the angle φ_n of the next triangle n is:^[1]

\varphi _{n}=\arctan \left({\frac {1}{\sqrt {n}}}\right).

The sum of the angles of the first k triangles is called the total angle φ(k) for the kth triangle. It grows proportionally to the square root of k, with a bounded correction term c₂:^[1]

\varphi \left(k\right)=\sum _{n=1}^{k}\varphi _{n}=2{\sqrt {k}}+c_{2}(k)

where

\lim _{k\to \infty }c_{2}(k)=-2.157782996659\ldots

( A105459).

A triangle or section of spiral

Radius

The growth of the radius of the spiral at a certain triangle n is

\Delta r={\sqrt {n+1}}-{\sqrt {n}}.

Archimedean spiral

The Spiral of Theodorus approximates the Archimedean spiral.^[1] Just as the distance between two windings of the Archimedean spiral equals mathematical constant pi, as the number of spins of the spiral of Theodorus approaches infinity, the distance between two consecutive windings quickly approaches π.^[6]

The following is a table showing of two windings of the spiral approaching pi:

Winding No.:	Calculated average winding-distance	Accuracy of average winding-distance in comparison to π
2	3.1592037	99.44255%
3	3.1443455	99.91245%
4	3.14428	99.91453%
5	3.142395	99.97447%
→ ∞	→ π	→ 100%

As shown, after only the fifth winding, the distance is a 99.97% accurate approximation to π.^[1]

Continuous curve

The question of how to interpolate the discrete points of the spiral of Theodorus by a smooth curve was proposed and answered in (Davis 1993, pp. 37–38) by analogy with Euler's formula for the gamma function as an interpolant for the factorial function. Davis found the function

T(x)=\prod _{k=1}^{\infty }{\frac {1+i/{\sqrt {k}}}{1+i/{\sqrt {x+k}}}}\qquad (-1<x<\infty )

which was further studied by his student Leader^[7] and by Iserles (in an appendix to (Davis 1993) ). An axiomatic characterization of this function is given in (Gronau 2004) as the unique function that satisfies the functional equation

f(x+1)=\left(1+{\frac {i}{\sqrt {x+1}}}\right)\cdot f(x),

the initial condition $f(0)=1,$ and monotonicity in both argument and modulus; alternative conditions and weakenings are also studied therein. An alternative derivation is given in (Heuvers, Moak & Boursaw 2000).

Some have suggested a different interpolant which connects the spiral and an alternative inner spiral, as in (Waldvogel 2009).

References

1 2 3 4 5 . Also, this was used to visualize certain things in nature Hahn, Harry K. "The Ordered Distribution of Natural Numbers on the Square Root Spiral". arXiv:0712.2184.
↑ Nahin, Paul J. (1998), An Imaginary Tale: The Story of [the Square Root of Minus One], Princeton University Press, p. 33, ISBN 0-691-02795-1
↑ Plato; Dyde, Samuel Walters (1899), The Theaetetus of Plato, J. Maclehose, pp. 86–87.
1 2 Long, Kate. "A Lesson on The Root Spiral". Archived from the original on 4 April 2013. Retrieved 30 April 2008.
↑ Erich Teuffel, Eine Eigenschaft der Quadratwurzelschnecke, Math.-Phys. Semesterber. 6 (1958), pp. 148-152.
↑ Hahn, Harry K. (2008). "The distribution of natural numbers divisible by 2, 3, 5, 7, 11, 13, and 17 on the Square Root Spiral". arXiv:0801.4422.
↑ Leader, J.J. The Generalized Theodorus Iteration (dissertation), 1990, Brown University

Davis, P. J. (1993), Spirals from Theodorus to Chaos
Gronau, Detlef (March 2004), "The Spiral of Theodorus", The American Mathematical Monthly, Mathematical Association of America, 111 (3): 230–237, doi:10.2307/4145130, JSTOR 4145130
Heuvers, J.; Moak, D. S.; Boursaw, B (2000), "The functional equation of the square root spiral", in T. M. Rassias, Functional Equations and Inequalities, pp. 111–117
Waldvogel, Jörg (2009), Analytic Continuation of the Theodorus Spiral (PDF)

Ancient Greek mathematics

Mathematicians	Anaxagoras Anthemius Archytas Aristaeus the Elder Aristarchus Apollonius Archimedes Autolycus Bion Bryson Callippus Carpus Chrysippus Cleomedes Conon Ctesibius Democritus Dicaearchus Diocles Diophantus Dinostratus Dionysodorus Domninus Eratosthenes Eudemus Euclid Eudoxus Eutocius Geminus Heron Hipparchus Hippasus Hippias Hippocrates Hypatia Hypsicles Isidore of Miletus Leon Marinus Menaechmus Menelaus Metrodorus Nicomachus Nicomedes Nicoteles Oenopides Pappus Perseus Philolaus Philon Porphyry Posidonius Proclus Ptolemy Pythagoras Serenus Simplicius Sosigenes Sporus Thales Theaetetus Theano Theodorus Theodosius Theon of Alexandria Theon of Smyrna Thymaridas Xenocrates Zeno of Elea Zeno of Sidon Zenodorus

Treatises	Almagest Archimedes Palimpsest Arithmetica Conics (Apollonius) Elements (Euclid) On the Sizes and Distances (Aristarchus) On Sizes and Distances (Hipparchus) On the Moving Sphere (Autolycus) The Sand Reckoner

Problems	Problem of Apollonius Squaring the circle Doubling the cube Angle trisection

Centers	Cyrene Library of Alexandria Platonic Academy

Timeline of Ancient Greek mathematicians

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