Addition Zones (0-18)

Addition is the form of an expression set equal to zero as the additive identity which is common practice in several areas of mathematics.

Tip

This section is referring to wiki page-1 of zone section-1 that is inherited from the zone section- by prime spin-0 and span- with the partitions as below.

  1. True Prime Pairs
  2. Primes Platform
  3. Pairwise Scenario
  4. Power of Magnitude
  5. The Pairwise Disjoint
  6. The Prime Recycling ζ(s)
  7. Implementation in Physics

By the Euler's identity this addition should form as one (1) unit of an object originated by the 18s structure. For further on let's call this unit as the base unit.

The 24 Cells Hexagon

Below is the list of primes spin along with their position, the polarity of the number, and the prime hexagon's overall rotation within 1000 numbers.

Note

The Prime Hexagon is a mathematical structure developed by mathematician Tad Gallion. A Prime Hexagon is formed when integers are sequentially added to a field of tessellating equilateral triangles, where the path of the integers is changed whenever a prime number is encountered (GitHub: kaustubhcs/prime-hexagon).

5, 2, 1, 0
7, 3, 1, 0
11, 4, 1, 0
13, 5, 1, 0
17, 0, 1, 1
19, 1, 1, 1
23, 2, 1, 1
29, 2, -1, 1
31, 1, -1, 1
37, 1, 1, 1
41, 2, 1, 1
43, 3, 1, 1
47, 4, 1, 1
53, 4, -1, 1
59, 4, 1, 1
61, 5, 1, 1
67, 5, -1, 1
71, 4, -1, 1
73, 3, -1, 1
79, 3, 1, 1
83, 4, 1, 1
89, 4, -1, 1
97, 3, -1, 1
101, 2, -1, 1
103, 1, -1, 1
107, 0, -1, 1
109, 5, -1, 0
113, 4, -1, 0
127, 3, -1, 0
131, 2, -1, 0
137, 2, 1, 0
139, 3, 1, 0
149, 4, 1, 0
151, 5, 1, 0
157, 5, -1, 0
163, 5, 1, 0
167, 0, 1, 1
173, 0, -1, 1
179, 0, 1, 1
181, 1, 1, 1
191, 2, 1, 1
193, 3, 1, 1
197, 4, 1, 1
199, 5, 1, 1
211, 5, -1, 1
223, 5, 1, 1
227, 0, 1, 2
229, 1, 1, 2
233, 2, 1, 2
239, 2, -1, 2
241, 1, -1, 2
251, 0, -1, 2
257, 0, 1, 2
263, 0, -1, 2
269, 0, 1, 2
271, 1, 1, 2
277, 1, -1, 2
281, 0, -1, 2
283, 5, -1, 1
293, 4, -1, 1
307, 3, -1, 1
311, 2, -1, 1
313, 1, -1, 1
317, 0, -1, 1
331, 5, -1, 0
337, 5, 1, 0
347, 0, 1, 1
349, 1, 1, 1
353, 2, 1, 1
359, 2, -1, 1
367, 1, -1, 1
373, 1, 1, 1
379, 1, -1, 1
383, 0, -1, 1
389, 0, 1, 1
397, 1, 1, 1
401, 2, 1, 1
409, 3, 1, 1
419, 4, 1, 1
421, 5, 1, 1
431, 0, 1, 2
433, 1, 1, 2
439, 1, -1, 2
443, 0, -1, 2
449, 0, 1, 2
457, 1, 1, 2
461, 2, 1, 2
463, 3, 1, 2
467, 4, 1, 2
479, 4, -1, 2
487, 3, -1, 2
491, 2, -1, 2
499, 1, -1, 2
503, 0, -1, 2
509, 0, 1, 2
521, 0, -1, 2
523, 5, -1, 1
541, 5, 1, 1
547, 5, -1, 1
557, 4, -1, 1
563, 4, 1, 1
569, 4, -1, 1
571, 3, -1, 1
577, 3, 1, 1
587, 4, 1, 1
593, 4, -1, 1
599, 4, 1, 1
601, 5, 1, 1
607, 5, -1, 1
613, 5, 1, 1
617, 0, 1, 2
619, 1, 1, 2
631, 1, -1, 2
641, 0, -1, 2
643, 5, -1, 1
647, 4, -1, 1
653, 4, 1, 1
659, 4, -1, 1
661, 3, -1, 1
673, 3, 1, 1
677, 4, 1, 1
683, 4, -1, 1
691, 3, -1, 1
701, 2, -1, 1
709, 1, -1, 1
719, 0, -1, 1
727, 5, -1, 0
733, 5, 1, 0
739, 5, -1, 0
743, 4, -1, 0
751, 3, -1, 0
757, 3, 1, 0
761, 4, 1, 0
769, 5, 1, 0
773, 0, 1, 1
787, 1, 1, 1
797, 2, 1, 1
809, 2, -1, 1
811, 1, -1, 1
821, 0, -1, 1
823, 5, -1, 0
827, 4, -1, 0
829, 3, -1, 0
839, 2, -1, 0
853, 1, -1, 0
857, 0, -1, 0
859, 5, -1, -1
863, 4, -1, -1
877, 3, -1, -1
881, 2, -1, -1
883, 1, -1, -1
887, 0, -1, -1
907, 5, -1, -2
911, 4, -1, -2
919, 3, -1, -2
929, 2, -1, -2
937, 1, -1, -2
941, 0, -1, -2
947, 0, 1, -2
953, 0, -1, -2
967, 5, -1, -3
971, 4, -1, -3
977, 4, 1, -3
983, 4, -1, -3
991, 3, -1, -3
997, 3, 1, -3

Including the 1st (2) and 2nd prime (3) all together will have a total of 168 primes. The number of 168 it self is in between 39th (167) and 40th prime (173).

Tip

The number of primes less than or equal to a thousand (π(1000) = 168) equals the number of hours in a week (7 * 24 = 168).

247

The most obvious interesting feature of proceeding this prime hexagon, the number line begins to coil upon itself, is it confines all numbers of primes spin!

Note

Each time a prime number is encountered, the spin or ‘wall preference’ is switched. So, from the first cell, exit from 2’s left side. This sets the spin to left and the next cell is 3, a prime, so switches to right. 4 is not prime and continues right. 5 is prime, so switch to left and so on. (HexSpin)

Defining the Prime Hexagon

As the number line winds about toward infinity, bending around prime numbers, it never exits the 24 cells. And it is the fact that 168 divided by 24 is exactly seven (7).

Note

Surprisingly, the 24-cell hexagon confines all natural numbers. The reason: no prime numbers occupy a cell with a right or left wall on the t-hexagon’s outer boundary, other than 2 and 3, the initial primes that forced the number line into this complex coil. Without a prime number in the outer set of triangles, the number line does not change to an outward course and remains forever contained in the 24 cells. (HexSpin)

Euler Partition

You may notice that there are twists and turns until 19 abuts 2 therefore this addition zone takes only the seven (7) primes out of the 18's structure of True Prime Pairs.

$True Prime Pairs:
(5,7), (11,13), (17,19)
 
layer | node | sub |  i  |  f
------+------+-----+----------
      |      |     |  1  | --------------------------
      |      |  1  +-----+                           |    
      |  1   |     |  2  | (5)                       |
      |      |-----+-----+                           |
      |      |     |  3  |                           |
  1   +------+  2  +-----+----                       |
      |      |     |  4  |                           |
      |      +-----+-----+                           |
      |  2   |     |  5  | (7)                       |
      |      |  3  +-----+                           |
      |      |     |  6  |                          11s
------+------+-----+-----+------      } (36)         |
      |      |     |  7  |                           |
      |      |  4  +-----+                           |
      |  3   |     |  8  | (11)                      |
      |      +-----+-----+                           |
      |      |     |  9  |                           |
  2   +------|  5  +-----+-----                      |
      |      |     |  10 |                           |
      |      |-----+-----+                           |
      |  4   |     |  11 | (13) ---------------------
      |      |  6  +-----+
      |      |     |  12 |---------------------------
------+------+-----+-----+------------               |
      |      |     |  13 |                           |
      |      |  7  +-----+                           |
      |  5   |     |  14 | (17)                      |
      |      |-----+-----+                           |
      |      |     |  15 |                           7s √
  3   +------+  8  +-----+-----       } (36)         |
      |      |     |  16 |                           |
      |      |-----+-----+                           |
      |  6   |     |  17 | (19)                      |
      |      |  9  +-----+                           |
      |      |     |  18 | --------------------------
------|------|-----+-----+------

The tessellating field of equilateral triangles fills with numbers, with spin orientation flipping with each prime number encountered, creating 3 minor hexagons.

Tip

Prime numbers are numbers that have only 2 factors: 1 and themselves.

  • For example, the first 5 prime numbers are 2, 3, 5, 7, and 11. By contrast, numbers with more than 2 factors are call composite numbers.
  • 1 is not a prime number because it can not be divided by any other integer except for 1 and itself. The only factor of 1 is 1.
  • On the other hand, 1 is also not a composite number because it can not be divided by any other integer except for 1 and itself.

In conclusion, the number 1 is neither prime nor composite.

π(6+11) = π(17) = 7

So there should be a tight connection between 168 primes within 1000 with the 24-cell hexagon. Indeed it is also correlated with 1000 prime numbers.

Undiscovered Features

When we continue the spin within the discussed prime hexagon with the higher numbers there are the six (6) internal hexagons within the Prime Hexagon.

Note

Cell types are interesting, but they simply reflect a modulo 6 view of numbers. More interesting are the six internal hexagons within the Prime Hexagon. Like the Prime Hexagon, they are newly discovered. The minor hexagons form solely from the order, and type, of primes along the number line (HexSpin).

Screen-Shot-2016-11-07-at-5 11 59-PM

So the most important thing that need to be investigated is why the prime spinned by module six (6). What is the special thing about this number six (6) in primes behaviour?

Note

Similarly, I have a six colored dice in the form of the hexagon. If I take a known, logical sequence of numbers, say 10, 100, 1000, 10000, and look at their spins in the hexagon, the resulting colors associated with each number should appear random – unless the sequence I’m investigating is linked to the nature of the prime numbers.

Moreover there are view statements mentioned by the provider which also bring us in to an attention like the modulo 6 above. We put some of them below.

Note

That is, if the powers of 10 all returned with blue spin, or as a series of rainbows, or evenly alternating colors or other non-random results, then I’d say prime numbers appear to have a linkage to 10. I may not know what the the linkage is, just that it appears to exist (HexSpin).

image

Another is that phi and its members have a pisano period if the resulting fractional numbers are truncated.

Note

I wondered if that property might hold for the incremental powers of phi as well. For this reason I chose to see numbers in the hexagon as quantum, and truncate off the decimal values to determine which integer cell they land in. That is what I found. Phi and its members have a pisano period if the resulting fractional numbers are truncated. (HexSpin).

truncated fractional numbers

It would mean that there should be undiscovered things hidden within the residual of this decimal values. In fact it is the case that happen with 3-forms in 7D.

Dimensional Algorithms

Let's consider a prime spin theory of compactifying the 7-dimensional manifold on the 3-sphere of a fixed radius and study its dimensional reduction to 4D.

Note

Proceeding, the number line begins to coil upon itself; 20 lands on 2’s cell, 21 on 3’s cell. Prime number 23 sends the number line left to form the fourth (4th) hexagon, purple. As it is not a twin, the clockwise progression (rotation) reverses itself. Twin primes 29 and 31 define the fifth (5th) hexagon, cyan. Finally, 37, again not a twin, reverses the rotation of the system, so 47 can define the yellow hexagon (HexSpin).

IMG_20231221_074421

Taking 19 as a certain parameter we can see that the left handed cycles are happen on 5th-spin (forms 4th hexagon, purple) and 6th-spin (forms 5th hexagon, cyan). Both have different rotation with other spin below 9th spin (forms 6th hexagon, yellow).

Note

All perfect squares within our domain (numbers not divisible by 2, 3 or 5) possess a digital root of 1, 4 or 7 and are congruent to either {1} or {19} modulo 30.

  • When the digital root of perfect squares is sequenced within a modulo 30 x 3 = modulo 90 horizon, beautiful symmetries in the form of period-24 palindromes are revealed. Here’s one modulo 90 spin on perfect squares.
  • parsing the squares by their mod 90 congruence reveals that there are 96 perfect squares generated with each 4 * 90 = 360 degree cycle,
  • which distribute 16 squares to each of 6 mod 90 congruence sub-sets defined as n congruent to {1, 19, 31, 49, 61, 79} forming 4 bilateral 80 sums.
  • each of the 6 columns has 8 bilateral 360 sums, tor a total of 48 * 360 = 40 * 432 (much more on the significance of number 432, elsewhere on this site).

There’s another hidden dimension of our domain worth noting involving multiples of 360, i.e., when framed as n ≌ {1, 7, 11, 13, 17, 19, 23, 29, 31, 37, 41, 43, 47, 49, 53 59, 61, 67, 71, 73, 77, 79, 83, 89} modulo 90, and taking ‘bipolar’ differentials of perfect squares (PrimesDemystified)

16 × 6 = 96

96 perfect squares

Also note, the digital roots of the Prime Root Set as well as the digital roots of Fibonnaci numbers and indexed to it all sum to 432 (48x9) in 360° cycles.

Note

Each of the digital root multiplication matrices produced by the six channels consists of what are known in mathematics as ‘Orthogonal Latin Squares’ (defined in Wikipedia as “an n x n array filled with n different symbols, each occurring exactly once in each row and exactly once in each column” … in our case every row and column of the repeating 6x6 matrices possesses the six elements: 1, 2, 4, 5, 7, 8 in some order). Also, the sum of the multiplicative digital roots = 108 x 24 = 2592 = 432 x 6.

  • Note: Channels A, D, E and F combined represent the set of natural numbers not divisible by 2, 3 and 5, the first 24 elements of which form the basis of the Magic Mirror Matrix.
  • The graphic below illustrates the transformative relationships between the matrices employing their primary building blocks (one of the sixteen identical 6 x 6 (36 element) Latin Squares that constitute each matrix)
  • When you rotate either the {1,4,7} or {2,5,8} magic square around its horizontal axis, i.e. columns {A,B,C} become {C,B,A}, then add the {1,4,7} {2,5,8} magic squares together, you produce a square with nine 9’s. For example, adding the first rows of each gives us: {2,8,5} + {7,1,4} = {9,9,9}.
  • Triangles and magic squares similar–or identical–to those shown above can be derived from the digital root sequence cycles of all three twin prime distribution channels (namely numbers ≌ to {11,13}, {17,19} and {1,29} modulo 30).
  • This is also true of dyads formed by paired radii of the Prime Spiral Sieve that sum to 30, i.e., numbers ≌ to {1,29}, {7,23}, {11,19}, or {13,17} modulo 30, as well as dyads formed when {n, n + 10} are ≌ to {1, 11}, {7, 17}, {13, 23} or {19, 29} modulo 30 (note their pairing by terminating digits). One example relating to twin primes: The first three candidate pairs in the twin prime distribution channel ≌ to {11,13} modulo 30 (all three of which are indeed twin primes) sequence their digital roots as follows:
    • {11,13} = digital roots 2 & 4
    • {41,43} = digital roots 5 & 7
    • {71,73} = digital roots 8 & 1.
  • As you can see, this is the same digital root sequence illustrated above. It appears that the triangulations and magic squares structuring the distribution of twin primes (and as it turns out, all prime numbers) have a genesis in universal principles involving symmetry groups rotated by the 8-dimensional algorithms discussed at length on this site.
  • You can see this universal principle at work, for example, with regard to the Fibonacci digital root sequence when coupled to a pair of dyads that follow certain incremental rules. As we illustrated above, the initializing dyad of the period-24 Fibonacci digital root sequence is {1,1, …}.

We can generate triangles and magic squares by tiering the Fibonacci digital root sequence with two pairs of terms that are + 3 or + 6 from the initial terms {1,1}. The values of the 2nd and 3rd tiers, or rows, must differ, or symmetry is lost. In other words, the first two columns should read either {1,4,7 + 1,7,4, or vice versa} but not {1,4,7 + 1,4,7, or 1,7,4, + 1,7,4}. (PrimesDemystified)

Multiplication_Matrix_Transforms

The above seven (7) primes will act then as extended branes. This is what we mean by addition zones and it happens whenever a cycle is restarted.

Equidistant Points

Note

When these 9 squares are combined and segregated to create a 6 x 6 (36 element) square, and this square is compared to the Vedic Square minus its 3’s, 6’s and 9’s (the result dubbed “Imaginary Square”), you’ll discover that they share identical vertical and horizontal secquences, though in a different order (alternating +2 and -2 from each other), and that these can be easily made to match exactly by applying a simple function multiplier, as described and illustrated later below. (PrimesDemystified)

ReciprocalTransform

They are the source of triangular coordinates when translated into vertices of a modulo 9 circle which by definition has 9 equidistant points each separated by 40°.

Note

When we additively sum the three period-24 digital root cycles these dyads produce, then tier them, we create six 3 x 3 matrices (each containing values 1 thru 9) separated by repetitive number tiers in the following order: {1,1,1} {5,5,5} {7,7,7} {8,8,8} {4,4,4} {2,2,2}.

  • The six (6) matrices these tiers demarcate are the source of triangular coordinates when translated into vertices of a modulo 9 circle (which by definition has 9 equidistant points around its circumference, each separated by 40°).
  • The series of diagrams below show the six geometric stages culminating in a complex polygon of extraordinary beauty. We’ve dubbed this object a ‘palindromagon’ given that the coordinates of the 18 triangulations produced by the digital root dyadic cycles in the order sequenced sum to a palindrome: 639 693 963 369 396 936.
  • Remarkably, this periodic palindrome, with additive sum of 108, sequences the 6 possible permutations of values {3,6,9}. Interesting to consider a geometric object with a hidden palindromic dimension. But that’s not all: When the six triadic permutations forming the palindrome are labeled A, B, C, D, E, F in the order generated, ACE and BDF form 3 x 3 Latin squares. In both cases all rows, columns and principal diagonals sum to 18:

    • ACE … BDF
    • 693 … 639
    • 369 … 963
    • 936 … 396
  • The output of these algorithmically sequenced triangulations is fundamentally a geometric representation of the twin prime distribution channels (and, as we noted above, the same geometry is expressed in factorization sequencing, albeit the vertices may be ordered differently.
  • This is because each set of three generator dyads roots to the same six elements: 1, 2, 4, 5, 7, 8. Thus, for example, dyad sets ({1,2} {4,5} {7,8}) and ({2,4} {5,7} {8,1}) will generate identical complex polygons, despite their vertices being sequenced in different orders.).

It’s remarkable that objects consisting of star polygons, spiraling irregular pentagons, and possessing nonagon perimeters and centers, can be constructed from only 27 coordinates pointing to 9 triangles in 3 variations. Each period-24 cycle produces two ‘palindromagons’. (PrimesDemystified)

Twin_Prime_Digital_Root_Polygon

Note

In our approach a 3-form is not an object that exist in addition to the metric, it is the only object that exist and in particular the 4D metric, is defined by the 3-form.

  • We would like to say that our present use of G2 structures (3-forms in 7D) is different from whatone can find in the literature on Kaluza–Klein compactifications of supergravity.
  • We show that the resulting 4D theory is (Riemannian) General Relativity (GR) in Plebanski formulation, modulo corrections that are negligible for curvatures smaller than Planckian.
  • Possibly the most interesting point of this construction is that the dimensionally reduced theory is GR with a non-zero cosmological constant, and the value of the cosmological constant is directly related to the size of . Realistic values of Λ correspond to of Planck size.

Also, in the supergravity context a 7D manifold with a G2 structure is used for compactifying the 11D supergravity down to 4D. In contrast, we compactify from 7D to 4D. (General relativity from three-forms in seven dimensions - pdf)

Standard Spin

Consistent Truncation

The the main reason of assigning two (2) profiles instead of only one (1) is that we have to accommodate the major type of primes numbers called twin primes.

Note

This is a necessary but not sufficient condition for N to be a prime as noted, for example, by N= 6(4)+1= 25, which is clearly composite. We note that each turn of the spiral equals an increase of six units. This means that we have a mod(6) situation allowing us to write: N mod(6)=6n+1 or N mod(6)=6n-1 (equivalent to 6n+5). (HexSpiral-Pdf)

twin primes

Note

Focusing on just the twin prime distribution channels, we see the relationships shown below [and, directly above, we show that two of the channels (B & C) transform bi-directionally by rotating 180° around one of their principal (lower-left to upper-right) diagonal axes]:

7th spin - 4th spin = (168 - 102)s = 66s = 6 x 11s = 30s + 36s

Twin_Primes_Channel_Matrices (1)

By the Δ(19 vs 18) Scenario those three are exactly landed in the 0's cell out of Δ18. See that the sum of 30 and 36 is 66 while the difference between 36 and 102 is also 66.

Note

You likely noticed I began with 2 rather than 1 or 0 when I first constructed the hexagon. Why? Because they do not fit inside — they stick off the hexagon like a tail. Perhaps that’s where they belong. However, if one makes a significant and interesting assumption, then 1 and 0 fall in their logical locations – in the 1 and 0 cells, respectively. _(HexSpin)

0 + 30 + 36 + 102 = 168 = π(1000)

0, 1 and negative numbers

Note

Because the value 30 is the first (common) product of the first 3 primes. And this 30th order repeats itself to infinity. Even in the first 30s system, therefore, the positions are fixed in which the number information positions itself to infinity. We call it the first member of the MEC 30.

  • The numbers not divisible by 2, 3 or 5 are highlighted. We call them prime positions, hence 1, 7, 11, 13, 17, 19, 23, 29. Important for our work is that in the following the term prime refers only to prime numbers that are in the prime positions. So primes 2, 3 and 5 are always excluded.
  • These positions: 1 7 11 13 17 19 23 29. We refer to this basic system as MEC 30 - “Mathematical Elementary Cell 30”. By repeating the positions we show the function of the basic system in the next step. If we extend the 30th order of the MEC, for example, to the number 120, the result is 4 times a 30th order and thus 4 × 8 = 32 prime positions.
  • Hypothetical assumption: If the product of the primes (except 2, 3, 5,) would not fall into the prime positions, thus be divided by 2, 3 or 5, the information would have 120 = 32 primes in 32 prime positions: 1, 7, 11, 13, 17, 19, 23, 29, / 31, 37, 41, 43, 47, 49, 53, 59, / 61, 67, 71, 73, 77, 79, 83, 89, / 91, 97, 101, 103, 107, 109, 113, 119
  • These forms gives prime positions: 1, 7, 11, 13, 17, 19, 23, 29, / 1, 7, 11, 13, 17, 19, 23, 29, / 1, 7, 11, 13, 17 , 19, 23, 29, / 1, 7, 11, 13, 17, 19, 23, 29. The 30th order is repeated in the number space 120 = 4 times, 4 × 8 = 32 prime positions, thus 4 terms.

From our consideration we can conclude that the distribution of prime numbers must have a static base structure, which is also confirmed logically in the further course. This static structure is altered by the products of the primes themselves, since these products must fall into the prime positions since they are not divisible by 2, 3 and 5. (Google Patent DE102011101032A9)

Note

Speaking of iterative digital division–a powerful tool for exposing structure–we get this astonishing equation: iteratively dividing the digital roots of the first 12 Fibonacci numbers times the divisively iterated 1000th prime, 7919, times 3604 gives us 1000. Keep in mind that the first two and last two digits of the Fibo sequence below, 11 and 89, sum to 100; that 89 is the 11th Fibo number; that there are 1000 primes between 1 and 892; and that 89 has the Fibonacci sequence embedded in its decimal expansion

112_2112_Prime_Pyramid

Hidden Dimensions

Note

The four faces of our pyramid additively cascade 32 four-times triangular numbers (oeis.org/A046092: a(n) = 2(n+1) …).

  • These include Fibo1-3 equivalent 112 (rooted in T7 = 28; 28 x 4 = 112), which creates a pyramidion or capstone in our model, and 2112 (rooted in T32 = 528; 528 x 4 = 2112), which is the index number of the 1000th prime within our domain, and equals the total number of ‘elements’ used to construct the pyramid.
  • Or, using the textbook way to visualize triangular numbers, 2112 = the total number of billiard balls filling the four faces, which in our case will be dually populated with natural numbers 1, 2, 3, … and their associated numbers not divisible by 2, 3, or 5 in a 4-fold progression of perfect squares descending the faces of the pyramid.

The table below shows the telescopic progressions of triangular, 4-times triangular numbers and cascade of perfect squares that populate the pyramid’s faces.

Pyramid_Triangular_Numbers

The equality between the product on the 1st-line and the formulas in the 3rd- and 4th-lines is Euler's pentagonal number where p(33) = 10143 landed exactly by n - 7.

Note

Using Euler’s method to find p(40): A ruler with plus and minus signs (grey box) is slid downwards, the relevant terms added or subtracted. The positions of the signs are given by differences of alternating natural (blue) and odd (orange) numbers. In the SVG file, hover over the image to move the ruler (Wikipedia).

π(π(π(1000th prime))) + 1 = 40

image

As explicitly indicated by n - 7 within identition zones this p(33) behave reversal to the exponentiation zones so it would stand as π(π(π(1000th prime)))+1.

p(33) = p(40-7) = loop (100000) = 4 + 25 + 139 + 1091 + 8884 = 10143

identities zones

So there would be the empty spaces for 18 - 7 = 11 numbers. By our project these spaces will be unified by all of the eleven (11) members of identition zones.

(11x7) + (29+11) + (25+6) + (11+7) + (4+1) = 77+40+31+18+5 = 171

extended branes

So by simple words this 11 dimensions brings us back to the root functions. The only difference is the base unit. It is now carrying the above p(33) = 10143.