Observer Patch Holography (OPH)

Observer Patch Holography starts from one claim: no observer sees the whole world at once. Each observer accesses only a local patch, and neighboring patches must agree on their overlap. OPH asks how much physics follows from that demand alone.

French version: README_FR.md

Quick links: website | Paper 1: synthesis | Paper 2: SM/GR derivation | Paper 3: particle derivation | OPH Book | OPH Lab | challenge

OPH is a reconstruction program for fundamental physics. Spacetime, gauge structure, particles, records, and observer synchronization are treated as consequences of overlap consistency on a finite holographic screen.

What OPH Delivers

• A finite-resolution theorem package for observer patches, collars, overlap repair, higher gauge structure, records, and checkpoint/restoration.
• A conditional route to Lorentzian geometry, modular time, Jacobson-type Einstein dynamics, and de Sitter static-patch cosmology.
• A compact gauge route to the realized Standard Model quotient SU(3) x SU(2) x U(1) / Z_6, together with the exact hypercharge lattice and the realized counting chain N_g = 3, N_c = 3.
• A particle program with exact structural massless carriers, theorem-grade electroweak closure, a quantitative Higgs/top stage, exact non-hadron mass sidecars, and explicit continuation lanes for flavor and hadrons.
• A concrete screen-microphysics architecture that puts measurement, records, and observers inside the physics.

Overall theorem and derivation stack

_{The full OPH stack from axioms to relativity, gauge structure, particles, observers, and the remaining open fronts. Click to open the full SVG.}

Particle Highlights

Theorem-grade and structural hits

• Exact structural zeros for the photon, gluons, and graviton.
• Electroweak closure on the D10 calibration chain, with target-free public W/Z rows and an exact frozen pair W = 80.377 GeV, Z = 91.18797809193725 GeV.
• A quantitative Higgs/top stage downstream of the electroweak core, with strong public forward rows H = 125.218922 GeV, t = 172.388646 GeV.

Exact non-hadron output surface

Lane	Exact output(s)	Status note
Structural carriers	m_photon = m_gluon = m_graviton = 0	theorem-grade structural exactness
Electroweak sidecar	W = 80.377 GeV, Z = 91.18797809193725 GeV	exact frozen repair surface
Higgs sidecar	H = 125.1995304097179 GeV	exact compare-only inverse slice
Charged witness	(e, mu, tau) = (0.00051099895, 0.1056583755, 1.7769324651340912) GeV	exact same-family witness
Quark witness	(u, d, s, c, b, t) = (0.00216, 0.00470, 0.0935, 1.273, 4.183, 172.3523553288311) GeV	exact same-family witness
Neutrino adapter	(m1, m2, m3) = (0.01745663295, 0.01948419960, 0.05308139066) eV with exact representative Δm21², Δm31², Δm32²	exact compare-only adapter

Particle derivation stack

_{A compact view of the particle lane. Click to open the full SVG.}

Continuation-grade particle successes

• The quark continuation lane emits public rows for u, d, s, c, and b on the selected D12 sheet.
• The neutrino weighted-cycle branch reaches the observed PMNS and hierarchy regime with theta12 = 34.2259°, theta23 = 49.7228°, theta13 = 8.68636°, delta = 305.581°, and Δm21² / Δm32² = 0.03072111.
• The exact non-hadron surface is collected in code/particles/EXACT_NONHADRON_MASSES.md.

Brief gap summary

The remaining particle gaps are narrow and explicit: charged leptons wait on C_hat_e^{cand} and mu_phys(Y_e), quarks wait on the one-scalar law quark_d12_t1_value_law on the selected D12 mass ray with intrinsic_scale_law_D12 as the derived wrapper, neutrinos wait on C_nu, and hadrons wait on the production backend bundle plus full production systematics.

Papers

• Paper 1. Observers Are All You Need: synthesis paper for the whole OPH stack.
• Paper 2. Recovering Relativity and Standard Model Structure from Observer-Overlap Consistency: SM/GR derivation paper for the recovered core.
• Paper 3. Deriving the Particle Zoo from Observer Consistency: particle derivation, exact-hit surface, and continuation map.
• Paper 4. Reality as a Consensus Protocol: fixed-point, repair, and consensus formulation.
• Paper 5. Screen Microphysics and Observer Synchronization: finite screen architecture, records, and observer machinery.

More

• Website: floatingpragma.io/oph
• Theory explainer: floatingpragma.io/oph/theory-of-everything
• Simulation-theory explainer: floatingpragma.io/oph/simulation-theory
• Book: oph-book.floatingpragma.io
• Lab: oph-lab.floatingpragma.io
• Common objections: extra/COMMON_OBJECTIONS.md
• IBM Quantum note: extra/IBM_QUANTUM_CLOUD.md

Repository Guide

• paper/: PDFs, LaTeX sources, and release metadata.
• book/: OPH Book source.
• code/: computational material, particle outputs, and experiments.
• assets/: public diagrams and figures.
• extra/: explainers, objections, and supporting notes.