CPP Gravity & GR Series — 4 Papers

Gravity & General Relativity from Discrete Primitives

Newtonian gravity, Schwarzschild & Kerr metrics, and quantum gravity phase noise all emerge from DI-bit vector summation on the 600-cell lattice—without spacetime curvature, tensors, or free parameters.

Overview

The CPP Gravity Series demonstrates how all gravitational phenomena emerge from purely discrete primitives. Conscious Points imprint displacement-increment (DI) bits at Grid Points, propagating vector sums that displace masses via Space Stress Scalar (SSS) gradients. The absolute component (aSSS) produces universal gravitation with natural 1/r² dilution from spherical spread.

Key achievements include deriving the gravitational constant G to 99.99% CODATA agreement, reproducing all classical GR tests (perihelion precession, light deflection, Shapiro delay, frame-dragging), naturally solving the vacuum energy problem (Λ ~ 10-120), and predicting a unique golden-ratio phase noise spectrum testable by LIGO/LISA in the 2030–2040 window.

Gravitational Constant
99.99% CODATA
G = 6.67430 × 10&sup-11;
Mercury Perihelion
42.98″/cy
99.99% agreement
Light Deflection
1.75″
99.9% agreement
Cosmological Constant
~10-120
Natural cancellation

The Papers

CPP-004 Gravity & GR from Discrete Primitives — The foundational paper deriving gravitational phenomena from DI-bit vector summation, SSS components, and emergent metric warping. CPP-004b Newtonian Gravitational Force Derivation — SSS bit diffusion, holographic recycling constraint, entropic attraction, and the origin of 1/r² from bit conservation. CPP-004c Schwarzschild & Kerr Metric Derivation — Gravity as a biased quantum-thermal ratchet: perihelion precession, light deflection, frame-dragging, and event horizons as saturation gradients. CPP-011 Quantum Gravity Phase Noise Prediction — A parameter-free prediction of golden-ratio-structured noise at the Planck scale, testable by LIGO O5, LISA, and MAGIS-100.

Falsifiable Predictions

The CPP gravity framework makes specific, testable predictions distinguishable from General Relativity and competing quantum gravity approaches:

  • CMB μ-distortions ~ 10-8 at ℓ > 3000 (within LiteBIRD sensitivity)
  • High-frequency gravitational wave cutoff > 1010 Hz from discrete lattice structure
  • 1.8% golden-ratio phase noise modulation detectable by LIGO O5 and LISA (2030–2040)
  • No singularities — event horizons appear as saturation gradients with information preservation

Related Series

CPP-001a

Foundations of CPP — Overview with full quantitative benchmark table

CPP-001b

Pre-Geometric Foundations & Strong Sector with hadron spectrum

CPP-014

Experimental Timeline — Eight predictions including GW phase noise

CPP-002

Electroweak Series — W/Z/Higgs mass derivations from lattice geometry

CPP-041

Quantum Mechanics Series — Wavefunction collapse & measurement