The model identifies the proton mass stability at the 64-bit limit (2^64). Since gravitational interaction scales with m_p^2 , the hierarchy gap corresponds to the square of that limit:
(2^64)^2 = 2^128
The geometric derivation involves a factor of 2, linked to the holographic pixel diagonal (√2 )^2:
2 / 2^128 = 2^−127
2^−127 represents the least significant bit (LSB) of a 128-bit integer.
Where does the 64 come from and what do you mean with 'proton mass stability'? The proton is believed to be stable because it is the lowest mass baryon. GUT theories say it might be unstable with a half time of at least 10^34. How does that relate to your number 64? Does the number have a unit?
64 is dimensionless. It comes from the model's holographic scaling law, where mass scales with surface complexity (m ∼ 4^i). The proton appears at i = 32.
4^32= (2^2)^32 = 2^64
2^64 seems to be the minimum information density required to geometrically define a stable volume. The proton stability implies that nothing simpler can sustain a 3D topology. This limit defines the object's topological complexity, not its lifespan.
Please note that the model is being developed with IA assistance, and I realize that the onthological base needs further refinement.
The terms (1 + α / 3) and 4^64 appear in the three derivations. All of them show the same discrepancy from the experimental value (8 ppm). (Note: There is a typo in the expected output of the previous Python script; it should yield a discrepancy of 8.39 ppm, not 6 ppm.)
Is it statistically plausible that this happens by chance? Are there any hidden tricks? AI will find a possible conceptualization for (almost) anything, but I'm trying to get an informed human point of view.
What is so special about 2^127?
The model identifies the proton mass stability at the 64-bit limit (2^64). Since gravitational interaction scales with m_p^2 , the hierarchy gap corresponds to the square of that limit:
The geometric derivation involves a factor of 2, linked to the holographic pixel diagonal (√2 )^2: 2^−127 represents the least significant bit (LSB) of a 128-bit integer.Where does the 64 come from and what do you mean with 'proton mass stability'? The proton is believed to be stable because it is the lowest mass baryon. GUT theories say it might be unstable with a half time of at least 10^34. How does that relate to your number 64? Does the number have a unit?
64 is dimensionless. It comes from the model's holographic scaling law, where mass scales with surface complexity (m ∼ 4^i). The proton appears at i = 32.
2^64 seems to be the minimum information density required to geometrically define a stable volume. The proton stability implies that nothing simpler can sustain a 3D topology. This limit defines the object's topological complexity, not its lifespan.Please note that the model is being developed with IA assistance, and I realize that the onthological base needs further refinement.
The proton mass (m_p) is derived as:
G is derived as: α_G is derived as: The terms (1 + α / 3) and 4^64 appear in the three derivations. All of them show the same discrepancy from the experimental value (8 ppm). (Note: There is a typo in the expected output of the previous Python script; it should yield a discrepancy of 8.39 ppm, not 6 ppm.)The model also derives α as:
Is it statistically plausible that this happens by chance? Are there any hidden tricks? AI will find a possible conceptualization for (almost) anything, but I'm trying to get an informed human point of view.