AVirtualMachineForExploringSpaceTimeAndBeyond : Display of 'pi' with 1.000 digits -base 10- on an helix -good point of view- (Visualisation de 'pi' avec 1.000 chiffres -base 10- sur une helice -bon point de vue-).

display of 'pi' with 1.000 digits -base 10- on an helix -good point of view- [Visualisation de 'pi' avec 1.000 chiffres -base 10- sur une hélice -bon point de vue-].

To each digit D inside [0,9] is associated an angle A(D) with the following rule:

                    A(D) = D.(2.pi/10)

Then each digit D(n) (n ∈ [1,...]) is displayed as a point (belonging to an helix) with the following tridimensional coordinates:

                    X = cos(A(D(n)))
                    Y = sin(A(D(n)))
                    Z = f(n)

'f' denoting an "arbitrary" function.

At last, the current picture displays all the segments {D(n),D(n+1)} (for n=1 to 999).

See some related pictures (including this one) displaying one circle -left-hand side picture- and two helices -midle and right-hand side pictures-:

The left-hand side picture -using a parallel projection, hence a circle-like structure- seems to exhibit extraordinary symmetries, when the right-hand side one shows that there are none. Obviously, those apparent symmetries are due to the fact that 'pi' is a normal number (not yet demonstrated -in 2019-) meaning that, for example, the frequencies of 00, 01, 02,..., 97, 98, 99 are equal (and equal to 1/100). Thus, whatever the digits p and q, one can find n such as D(n)=p and D(n+1)=q. Then all segments p ==> q must exist if a sufficient number of digits of 'pi' is computed (1000 for this picture -in fact 850 would be sufficient-)...

See the helix and the 20, 50 and 100 first digits:

[See the 100.000 first digits -base 10- of 'pi'.]
[Plus d'informations à ce sujet -en français/in french-]

See some related pictures (including this one):

pi.

The Golden Ratio.

The square root of 2.

Champernowne number.

[More pictures about these great mathematical constants]-

(CMAP28 WWW site: this page was created on 12/17/2015 and last updated on 08/24/2024 10:59:58 -CEST-)

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Copyright © Jean-François COLONNA, 2015-2024. Copyright © CMAP (Centre de Mathématiques APpliquées) UMR CNRS 7641 / École polytechnique, Institut Polytechnique de Paris, 2015-2024.

Copyright © Jean-François COLONNA, 2015-2024.
Copyright © CMAP (Centre de Mathématiques APpliquées) UMR CNRS 7641 / École polytechnique, Institut Polytechnique de Paris, 2015-2024.