x [⇔] y [⇔] w [⇔] k [⇔] [n]


p [⇔] p [⇔] p w [⇔] cuz [⇔] [n]


M [nn], d [nn], [SNN], [rdm].


Multiplication of n numbers, n numbers division, the result divided by multiplication.

Since the result is a sequence which is between 0 and 2.


Algebraic paradox graceli the web.


Imagine a web wherein each corner web is marked with a number which begins with the number 1.


And any number may be replaced by an unknown, or even a function, and where the results of sequences each function is replaced by an operational relationship with other sequences of other corner represented by numbers, unknown, or even functions and their sequences results. Or even by its medial or subsequences thus infinitely.


The function will determine the way forward on the web maze and as far as its limit, and the limit of threads and substring functions.


The path can be consecutive, or even alternating jumping values ​​and following progressions with alternating variables that change in a natural progressivdade, or even alternating.


Ie we have a graph of variables arrays.


Of course I am treated using the algebraic system apreesentado by graceli with its operating symbols and functions and sub-functions of the same.


As seen in algebraic calculation graceli entrelaçante.


T web with lines [the] with progressive values ​​1a 9.


Line B with alternate values ​​following the alternations [a, x, 0, w, w / pP].


C line with values ​​sguindo sin x, cos p. [n]. so on.

R f w [a, b, c] = q n progressive sequences.


And each result have other functions and sub-functions from sequential results. Where each sequence is another sub-function, thus infinitely.


Example.


[1 to 9], [a, x, 0, w, w / pP]. sin x, cos p. [n].

And following a medial system to rsultado y, following a progression to result from progressive variables.


[1 to 9], [a, x, 0, w, w / pP]. sin x, cos p. [n].


τ μ Δ δ [1 to 9], [a, x, 0, w, w / pP]. sin x, cos p. [n]


. [+] SFSS [substring sub].


the spiral graceli network.


Between arms of the spiral, and the spiral.

algebraic calculation graceli entrelaçante.
Where the functions and numbers produce twists to each other, like hair braids.

Which can be direct or indirect. and with the sequences with progressions, medial, or even to the nth stages that produce sub subsequences ..


Direct: Where is the operation of the first sequence to the last sequence on another set of sequence, or even alternate sequences.


1/1 = 1, 2/1 = 3/3 =

2/1 = 2/1 = 2/1 =


Indirect: where is alternating operation. In other words, we have a progression x 1 to 10, have there a toggle system which occurs as the result asks the toggle jumps.


Example: px / px.

1/1 = 1, 1/2 = 0.5, 1/3 =.

= 1/1 or 1 3/1 = 5/1.

Or 1/1 = 1/4 = 1/7 =

2/2 = 1/4 = 2/7 =

px / [⇔, ≁]

Medial =

μ 1/1 = 1, 1/2 = 0.5, 1/3 =.

Μ = 1/1 or 1 3/1 = 5/1.

Or, μ 1/1 = 1/4 = 1/7 =

μ 2/2 = 1/4 = 2/7 =

with sub functions =

x = sfsx sequence. Sub-function of the x sequence. 1/1 = 1, 1/2 = 0.5, 1/3 =.


X = 1, x = 0.5


Pssx / p =


Pssx / p / [a, x, 0, 1, p,. / PP] ,


Progression subsequence x / p = progression.


This calculation also makes the medial, medial more variables, or more subvariáveis.


Or even Pssx / Pssx / p [n] = Pssx / p / [Pssx / p] [n] =


Pssx / p / [Pssx / w] [n] [a, x, 0, 1, p,. / PP],. =


Or even alternating sequences of functions by Pssx / p =


Or even Shecaniah toggle functions by Pssx / p =


Pssx / p / [Pssx / p] [n] =


Pssx / Pssx / p [n] / Pssx / p / [Pssx / p] [n] =


Ie infinitesimal of second order, third, fourth, so infinitely, where each sub sub has other subs, so infinitely ..
Or we can have subsequences of sub infinittesimais.


Ssx / ssy / ssw .............. [n] = sssssssssssssfx ../ p ........ [n]. =


Geometry and trigonometry by algebraic twists.


This way you can build a geometry and trigonometry for sin, cos, tangents and angles infinitesimal algebra.


Ssx / ssy / ssw ... sen ... [n] = sssssssssssss.f. / P ... cos ..... [n]. =


And sequential infinitesimal angles.


Or even the symbols of graceli.


Pssx / Pssx / p [n] = Pssx / p / [Pssx / p] [n] =

Pssx / p / [Pssx / p] [n] =


Pssx / Pssx / p [n] / Pssx / p / [Pssx / p] [n] =


Ssx / ssy / ssw ... sen ... [n] = sssssssssssss.f. / P ... cos ..... [n]. = Or even the symbols of graceli.


Pssx / [⇔, ≁] Pssx / p [n] = Pssx / p / [⇔, ≁], [Pssx / p] [n] =


Pssx / p / [⇔, ≁], [Pssx / p] [n] =


Pssx / Pssx / p [n] / [⇔, ≁] Pssx / p / [Pssx / p] [n] =


Ssx / ssy / ssw ... sen ... [n] = sssssssssssss.f. / P. [⇔, ≁] .. cos ..... [n]. =


md τ μ Δ δ p / pp [a, x, 0, 1, p,. / pP] ,. m [n]. [⇔, ≁] [+] p / p P =


md τ μ Δ δ logx / x [n] [a, x, 0, 1, p,. / pP] ,. m [n]. [⇔, ≁] [+] logx / x [n] =


a = alternating.

Some symbols used for exposed and created pro graceli math is good to see some works that way previously published.