Prime Unit Identity
We are going to assign prime identity as a standard model that attempts to stimulate a quantum field model called eQuantum for the four (4) known fundamental forces.
This section is referring to wiki page- of zone section-0 that is from the zone section- by prime spin- and span- with the partitions as below.
/maps
- Addition Zones (0-18)
- Multiplication Zones (18-30)
- Symmetrical Breaking (spin 8)
- The Angular Momentum (spin 9)
- Entrypoint of Momentum (spin 10)
- The Mapping of Spacetime (spin 11)
- Similar Order of Magnitude (spin 12)
- Searching for The Graviton (spin 13)
- Elementary Retracements (spin 14)
- Recycling of Momentum (spin 15)
- Exchange Entrypoint (spin 16)
- The Mapping Order (spin 17)
- Magnitude Order (spin 18)
- Exponentiation Zones (30-36)
- Electrodynamics (maps)
- Dynamic Shape (0-18)
- Central Polarity (18-30)
- Symmetrical Breaking (spin 8)
- The Angular Momentum (spin 9)
- Entrypoint of Momentum (spin 10)
- The Mapping of Spacetime (spin 11)
- Similar Order of Magnitude (spin 12)
- Searching for The Graviton (spin 13)
- Elementary Retracements (spin 14)
- Recycling of Momentum (spin 15)
- Exchange Entrypoint (spin 16)
- The Mapping Order (spin 17)
- Magnitude Order (spin 18)
- Numeric Symmetries (30-36)
- Palindromic Sequence (36-102)
- Theory of Everything (span 12)
- Everything is Connected (span 11)
- Truncated Perturbation (span 10)
- Quadratic Polynomials (span 9)
- Fundamental Forces (span 8)
- Elementary Particles (span 7)
- Basic Transformation (span 6)
- Hidden Dimensions (span 5)
- Parallel Universes (span 4)
- Vibrating Strings (span 3)
- Series Expansion (span 2)
- Wormhole Theory (span 1)
- Quantum Gravity (feed)
- Chromodynamics (lexer)
- Electroweak Theory (parser)
- Grand Unified Theory (syntax)
- Electrodynamics (maps)
- Identition Zones (36-102)
- Theory of Everything (span 12)
- Everything is Connected (span 11)
- Truncated Perturbation (span 10)
- Quadratic Polynomials (span 9)
- Fundamental Forces (span 8)
- Elementary Particles (span 7)
- Basic Transformation (span 6)
- Hidden Dimensions (span 5)
- Parallel Universes (span 4)
- Vibrating Strings (span 3)
- Series Expansion (span 2)
- Wormhole Theory (span 1)
This presentation was inspired by theoretical works from Hideki Yukawa who in 1935 had predicted the existence of mesons as the carrier particles of strong nuclear force.
Addition Zones
Here we would like to explain the way of said prime identity on getting the arithmetic expression of an individual unit identity such as a taxicab number below.
It is a taxicab number, and is variously known as Ramanujan’s number and the Ramanujan-Hardy number, after an anecdote of the British mathematician GH Hardy when he visited Indian mathematician Srinivasa Ramanujan in hospital (Wikipedia).
These three (3) number are twin primes. We called the pairs as True Prime Pairs. Our scenario is mapping the distribution out of these pairs by taking the symmetrical behaviour of 36 as the smallest power (greater than 1) which is not a prime power.
The smallest square number expressible as the sum of four (4) consecutive primes in two ways (5 + 7 + 11 + 13 and 17 + 19) which are also two (2) couples of prime twins! (Prime Curios!).
$True Prime Pairs:
(5,7), (11,13), (17,19)
layer| i | f
-----+-----+---------
| 1 | 5
1 +-----+
| 2 | 7
-----+-----+--- } 36 » 6®
| 3 | 11
2 +-----+
| 4 | 13
-----+-----+---------
| 5 | 17
3 +-----+ } 36 » 6®
| 6 | 19
-----+-----+---------
Thus in short this is all about a method that we called as the 19 vs 18 Scenario of mapping the quantum way within a huge of primes objects (5 to 19) by lexering (11) the ungrammared feed (7) and parsering (13) across syntax (17).
Φ(1,2,3) = Φ(6,12,18) = Φ(13,37,61)
$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 |
------+------+-----+-----+------ } (36)
| | | 7 |
| | 4 +-----+
| 3 | | 8 | (11)
| +-----+-----+
| | | 9 |
2 +------| 5 +-----+-----
| | | 10 |
| |-----+-----+
| 4 | | 11 | (13)
| | 6 +-----+
| | | 12 |
------+------+-----+-----+------------------
| | | 13 |
| | 7 +-----+
| 5 | | 14 | (17)
| |-----+-----+
| | | 15 |
3 +------+ 8 +-----+----- } (36)
| | | 16 |
| |-----+-----+
| 6 | | 17 | (19)
| | 9 +-----+
| | | 18 |
------|------|-----+-----+------
The main background is that, as you may aware, the prime number theorem describes the asymptotic distribution of prime numbers which is still a major problem in mathematic.
Multiplication Zones
Instead of a proved formula we came to a unique expression called zeta function. This expression first appeared in a paper in 1737 entitled Variae observationes circa series infinitas.
This expression states that the sum of the zeta function is equal to the product of the reciprocal of one minus the reciprocal of primes to the powers. But what has this got to do with the primes? The answer is in the following product taken over the primes p (discovered by Leonhard Euler):
This issue is actually come from Riemann hypothesis, a conjecture about the distribution of complex zeros of the Riemann zeta function that is considered to be the most important of unsolved problems in pure mathematics.
In addition to the trivial roots, there also exist complex roots for real t. We find that the he first ten (10) non-trivial roots of the Riemann zeta function is occured when the values of t below 50. A plot of the values of ζ(1/2 + it) for t ranging from –50 to +50 is shown below. The roots occur each time the locus passes through the origin. (mathpages).
Meanwhile obtaining the non complex numbers it is easier to look at a graph like the one below which shows Li(x) (blue), R(x) (black), π(x) (red) and x/ln x (green); and then proclaim "R(x) is the best estimate of π(x)." Indeed it is for that range, but as we mentioned above, Li(x)-π(x) changes sign infinitely often, and near where it does, Li(x) would be the best value.
And we can see in the same way that the function Li(x)-(1/2)Li(x1/2) is ‘on the average' a better approximation than Li(x) to π(x); but no importance can be attached to the latter terms in Riemann's formula even by repeated averaging.
Exponentiation Zones
The problem is that the contributions from the non-trivial zeros at times swamps that of any but the main terms in these expansions.
A. E. Ingham says it this way: Considerable importance was attached formerly to a function suggested by Riemann as an approximation to π(x)… This function represents π(x) with astonishing accuracy for all values of x for which π(x) has been calculated, but we now see that its superiority over Li(x) is illusory… and for special values of x (as large as we please) the one approximation will deviate as widely as the other from the true value (primes.utm.edu).
Moreover in it was verified numerically, in a rigorous way using interval arithmetic, that The Riemann hypothesis is true up to 3 · 10^12. That is, all zeroes β+iγ of the Riemann zeta-function with 0<γ≤3⋅1012 have β=1/2.
We have Λ ≤ 0.2. The next entry is conditional on taking H a little higher than 10*13, which of course, is not achieved by Theorem 1. This would enable one to prove Λ < 0.19. Given that our value of H falls between the entries in this table, it is possible that some extra decimals could be wrought out of the calculation. We have not pursued this (arXiv:2004.09765).
This Euler formula represents the distribution of a group of numbers that are positioned at regular intervals on a straight line to each other. Riemann later extended the definition of zeta(s) to all complex numbers (except the simple pole at s=1 with residue one). Euler's product still holds if the real part of s is greater than one. Riemann derived the functional equation of zeta function.
The Riemann zeta function has the trivial zeros at -2, -4, -6, … (the poles of gamma(s/2)). Using the Euler product (with the functional equation) it is easy to show that all the other zeros are in the critical strip of non-real complex numbers with 0 < Re(s) < 1, and that they are symmetric about the critical line Re(s)=1/2. The unproved Riemann hypothesis is that all of the nontrivial zeros are actually on the critical line (primes.utm.edu).
If both of the above statements are true then mathematically this Riemann Hypothesis is proven to be incorrect because it only applies to certain cases or limitations. So first of all the basis of the Riemann Hypothesis has to be considered.
The solution is not only to prove Re(z)= 1/2 but also to calculate ways for the imaginary part of the complex root of ζ(z)=0 and also to solve the functional equations. (Riemann Zeta - pdf)
On the other hand, the possibility of obtaining the function of the distribution of prime numbers shall go backwards since it needs significant studies to be traced.
Or may be start again from the Euler Function.
Identition Zones
Freeman Dyson discovered an intriguing connection between quantum physics and Montgomery's pair correlation conjecture about the zeros of the zeta function which dealts with the distribution of primes.
The Mathematical Elementary Cell 30 (MEC30) standard unites the mathematical and physical results of 1972 by the mathematician Hugh Montgomery and the physicist Freeman Dyson and thus reproduces energy distribution in systems as a path plan more accurately than a measurement. (Google Patent DE102011101032A9)
The path plan assume that a symmetric distribution of prime numbers with equal axial lengths from a middle zero axis = 15 is able to determine the distribution of primes in a given number space. This assumption finally bring us to the equation of Euler's identity.
Euler’s identity is considered to be an exemplar of deep mathematical beauty as it shows a profound connection between the most fundamental numbers. Three (3) of the basic arithmetic operations occur exactly once each: addition, multiplication, and exponentiation (Wikipedia).
The finiteness position of Euler's identity by the said MEC30 opens up the possibility of accurately representing the self-similarity based on the distribution of True Prime Pairs so that all number would belongs together with their own identitities.
Theories Of Everything (TOE), which integrate Grand Unified Theories (GUTs) with a quantum gravity theory face a greater barrier, because no quantum gravity theories, which include string theory, loop quantum gravity, and twistor theory, have secured wide acceptance. Following is the list of current status.
- The four components of the Higgs field (squares) break the electroweak symmetry and interact with other particles to give them mass, with three of the components becoming part of the massive W and Z bosons (0-30).
- Attempts to TOE show unification of the four forces called GUTs and have been partially successful, with connections proven between weak forces in electroweak theory and quantum electrodynamics (31).
- Some theories look for a graviton to complete the Standard Model list of force-carrying particles, while others, like loop quantum gravity, emphasize the possibility that time-space itself may have a quantum aspect to it (32).
- The strong force is carried by eight proposed particles called gluons, which are intimately connected to a quantum number called color, their governing theory is thus called quantum chromodynamics (33).
- The exchange of virtual pions along with vector, rho and omega mesons, provides an explanation for the residual strong force between nucleons. Allowed decays of the neutral Higgs boson, H, (circled) satisfy electroweak charge conservation (34).
- Unification of the strong force is expected at such high energies that it cannot be directly tested, but it may have observable consequences in the following unobserved decay of the proton (35).
- Pions are not produced in radioactive decay, but commonly are in high-energy collisions between hadrons. Pions also result from some matter–antimatter annihilation events (36-102).
By prime hexagon those milestones 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.
0 + 30 + 36 + 102 = 168 = π(1000)
Although unification of forces is generally anticipated, much remains to be done to prove its validity (College Physics 2e - Pdf). As an alternative solution let’s consider to assign this prime identity per IREE’s plan:
IREE (Intermediate Representation Execution Environment) is an MLIR-based end-to-end compiler and runtime that lowers Machine Learning (ML) models to a unified IR.
Nothing is going to be easly about the nature of prime numbers but they demonstrably congruent to something organized. Let's discuss starting with the addition zones.
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