#!/usr/bin/env python3 """ Computation 89 -- substrate Higgs Hamiltonian derivation (Z^2 bridge step 1) ============================================================================= Substrate-side closure for the ZĀ² bridge: derive the substrate-side Higgs Hamiltonian H_Higgs(C) from substrate primitives, with the goal of closing the KO-tempered Bernoulli MGF identification: Z^2 = lambda_SM(M_*) / b(M_*) <-?-> E_mu[exp(-(KO_total mod 8) X_bar)] Comp 88 established the RIGHT-HAND SIDE structurally (asymptotic Bernoulli MGF at KO-temperature beta = 2 delivers e^{-1}). Comp 89 attacks the LEFT-HAND SIDE: identifying H_Higgs(C) such that the substrate Bernoulli expectation E_mu[exp(-beta H_Higgs)] equals the substrate-side Higgs partition function. STRUCTURAL DERIVATION OF H_Higgs(C) = X_bar(C) ------------------------------------------------ The substrate Higgs field on substrate configurations C in P(D) must satisfy three structural constraints: (i) ADDITIVITY (independent Bernoulli bits). The substrate measure mu = otimes Bern(1/2) factors across sites. An extensive Hamiltonian must be additive: H(C) = sum_a h_a(B_a) where B_a = 1[a in C] is the bit at site a, h_a a per-site contribution. (ii) MATCHED SCALING (per-site energy 1/D). At matched scaling Lambda = sqrt(D), the substrate's energy units are rescaled by 1/Lambda^2 = 1/D. Per-site energy is therefore 1/D. (iii) UNIFORMITY (symmetric Bernoulli sites). P1 distinguishability treats all sites equivalently; no site is privileged in the Bernoulli measure. Per-site energy h_a is uniform across a. Together, (i)-(iii) force: H_Higgs(C) = (1/D) sum_a B_a = X_bar(C) This is the SIMPLEST possible substrate-Higgs Hamiltonian: empirical mean of bit-occupation. No free parameters, no model choice. All three ingredients trace to P1 + matched-scaling. BRIDGE IDENTIFICATION (PARTIAL CLOSURE) ---------------------------------------- With H_Higgs(C) = X_bar(C) derived structurally, the KO-tempered Bernoulli partition function is: Z_H(beta) := E_mu[exp(-beta H_Higgs(C))] = E_mu[exp(-beta X_bar)] At KO-temperature beta = KO_total mod 8 = 2: Z_H(2) -> exp(-1) asymptotically (Comp 88) The SUBSTRATE-SIDE bridge is now closed structurally: e^{-1} = Z_H(beta_KO) = E_mu[exp(-(KO_total mod 8) X_bar)] with all ingredients (H_Higgs, beta_KO, asymptotic limit) derived from P1 + 10-foundational + matched-scaling. REMAINING OPEN GAP (SM-SIDE) ---------------------------- Why does the SM Higgs coupling ratio Z^2 = lambda_SM(M_*) / b(M_*) equal the substrate-side Z_H(beta_KO) at the matched scaling? The candidate physical correspondence: at the matched scaling M_*, the SM Higgs quartic equals the LG quartic times the substrate's KO-tempered partition function: lambda_SM(M_*) = b * Z_H(beta_KO) = (1/4) * exp(-1) ā‰ˆ 0.0920 NUMERICAL VERIFICATION ---------------------- Observed lambda_SM(M_*) ā‰ˆ 0.0926 (Buttazzo et al. 2013) Predicted from bridge: (1/4) * exp(-1) ā‰ˆ 0.0920 Ratio: 0.0926 / 0.0920 = 1.008 -- the same 0.8% near-coincidence as Z^2. STATUS ------ Comp 89 closes the SUBSTRATE SIDE of the Z^2 bridge: H_Higgs = X_bar is structurally derived (additivity + matched scaling + uniformity), and the KO-tempered partition function delivers e^{-1} asymptotically. What remains is the SM-side identification: deriving lambda_SM(M_*) = b * Z_H(beta_KO) from a Connes-Chamseddine partition-function correspondence (rather than the obstructed heat-kernel correspondence of Comps 85, 86). This is the new v24.22+ research thread. Comp 89 reduces the remaining-open content of Z^2 to a single specific question: WHY does the SM Higgs effective coupling at the matched scaling M_* equal the LG quartic times the substrate's KO-tempered Bernoulli partition function? A candidate answer: a discrete-substrate analogue of the Connes-Chamseddine spectral-action correspondence operating at the partition-function level rather than the heat-kernel level. Future research. """ from __future__ import annotations import math import numpy as np def H_Higgs(C: set, D: int) -> float: """Substrate Higgs Hamiltonian: H(C) = X_bar(C) = |C|/D.""" return len(C) / D def Z_H_exact(D: int, beta: float, n_samples: int = 100_000, rng_seed: int = 42) -> float: """Empirical Bernoulli partition function E[exp(-beta H_Higgs)]. Uses Monte Carlo sampling of Bernoulli configurations. """ rng = np.random.default_rng(rng_seed) samples = rng.binomial(1, 0.5, size=(n_samples, D)) X_bars = samples.sum(axis=1) / D return float(np.mean(np.exp(-beta * X_bars))) def Z_H_analytic(D: int, beta: float) -> float: """Exact Bernoulli MGF at finite D: ((1 + exp(-beta/D))/2)^D.""" return ((1 + math.exp(-beta / D)) / 2) ** D def main(): print("=" * 100) print(" Computation 89 -- substrate Higgs Hamiltonian + Z^2 bridge step 1") print("=" * 100) print() print("STRUCTURAL DERIVATION: H_Higgs(C) = X_bar(C)") print("-" * 100) print() print(" Three constraints on substrate Higgs Hamiltonian:") print(" (i) ADDITIVITY: Bernoulli sites independent => H = sum_a h_a(B_a)") print(" (ii) MATCHED SCALING: per-site energy 1/D") print(" (iii) UNIFORMITY: P1 symmetry => h_a uniform across sites") print() print(" Forces: H_Higgs(C) = (1/D) sum_a B_a = X_bar(C)") print() print(" No free parameters. Derived from P1 + matched scaling.") print() print("KO-TEMPERED PARTITION FUNCTION Z_H(beta_KO)") print("-" * 100) print() beta_KO = 2 # KO_total mod 8 print(f" beta_KO = KO_total mod 8 = {beta_KO}") print() print(f" {'D':>8} {'Z_H analytic':>20} {'Z_H Monte Carlo':>20} {'asymptote':>15}") for D in [10, 100, 1000]: z_analytic = Z_H_analytic(D, beta_KO) z_mc = Z_H_exact(D, beta_KO) asymptote = math.exp(-1) print(f" {D:>8} {z_analytic:>20.10f} {z_mc:>20.10f} {asymptote:>15.10f}") print() print(f" Asymptotic limit (D -> infty): Z_H(beta_KO) = exp(-1) = {math.exp(-1):.10f}") print() print("BRIDGE IDENTIFICATION (PARTIAL)") print("-" * 100) print() print(" SUBSTRATE side (now closed structurally):") print(" Z_H(beta_KO) = E_mu[exp(-(KO_total mod 8) X_bar)] -> exp(-1)") print(" Ingredients: H_Higgs = X_bar (Comp 89), beta_KO = KO_total mod 8 = 2") print(" (10-foundational + Bott periodicity, Sec foundational-object),") print(" asymptotic limit (Cramer-Bernoulli machinery)") print() print(" CANDIDATE SM correspondence:") print(" lambda_SM(M_*) = b * Z_H(beta_KO) = (1/4) * exp(-1) ~ 0.0920") print(" OBSERVED lambda_SM(M_*) ~ 0.0926 (Buttazzo et al. 2013)") print(" RATIO 0.0926 / 0.0920 = 1.008 (the same 0.8% near-coincidence)") print() print("REMAINING OPEN GAP (SM-SIDE)") print("-" * 100) print() print(" Why does the SM Higgs quartic at matched scaling EQUAL the LG quartic times") print(" the substrate's KO-tempered partition function?") print() print(" Candidate answer (research direction): a discrete-substrate analogue of the") print(" Connes-Chamseddine spectral-action correspondence operating at the") print(" partition-function level rather than the heat-kernel level. The heat-kernel") print(" correspondence is structurally obstructed for discrete substrates (Comps 85,") print(" 86); the partition-function correspondence might survive.") print() print(" Comp 89 status: SUBSTRATE SIDE OF BRIDGE CLOSED. SM SIDE OPEN.") print() print(" Open content of Z^2 reduced to: derive the partition-function-level") print(" substrate-to-SM correspondence at matched scaling.") if __name__ == "__main__": main()