RTG → Geometry → GR – Relational Time Geometry

Version: v2.2 (Gold Standard, Pre-Axiom)
Date: 2025-11-25
Status: Conceptual and structural foundation, ready to be turned into Axiom Set v2.0.

Contents

0. Core Idea in One Sentence
Phase I – Micro Ontology: Resonant Nodes (No Spacetime)
Phase II – NS Bifurcation: Emergence of Complex Structure
Phase III – Non-Abelian Lift: Frustration → SU(2) / Quaternions
Phase IV – Pre-Geometric Structure Tensor and Tetrads
Phase V – Signature and Dimensionality
Phase VI – Metric and Connection
Phase VII – Torsion: Micro Nonzero, Macro Vanishing via Energy Minimization
- 7.1 Frustration Energy and Macroscopic Torsion
Phase VIII – Holonomy and Curvature
Phase IX – Continuum Manifold as Inverse Limit
Phase X – Low-Energy Gravity: Einstein–Hilbert Dominant
Phase XI – Quantum RTG (Sketch)
Phase XII – Phenomenology and the RTG Radion
Phase XIII – What RTG Explains vs What GR Assumes
Phase XIV – Final Pipeline Summary (v2.2)

0. Core Idea in One Sentence

Relational Time Geometry (RTG) starts from purely relational oscillator nodes (frequencies, phases, spins) on a graph, with no spacetime assumed. Through a sequence of dynamical bifurcations and algebraic lifts, it produces:

a complex structure via Neimark–Sacker (NS) bifurcation,
a quaternionic/SU(2) frame field via frustration,
a pre-geometric structure tensor,
tetrads, Lorentzian signature, torsion and curvature,
a continuum manifold as an inverse limit,
and a low-energy Einstein–Hilbert effective theory.

Spacetime is not the starting point; it is the output.

Phase I – Micro Ontology: Resonant Nodes (No Spacetime)

Status: Solid (simulated, conceptually clear)

Primitive entities:

Nodes \( i \) with:
- frequency \( \omega_i \in \mathbb{R}_+ \)
- phase \( \phi_i \in S^1 \)
- spin label \( s_i \in \{+i,-i\} \)
Resonance kernel \( \mathcal{R}_{ij}[\omega,\phi,s] \)
Couplings \( K_{ij} \), phase shifts \( B_{ij} \)

Schematic evolution:

\[\dot \phi_i = \omega_i + \sum_j K_{ij}\, \mathcal{R}_{ij}\, \sin(\phi_j – \phi_i – B_{ij})\]

No coordinates, no metric, no manifold. Just relational dynamics.

Phase II – NS Bifurcation: Emergence of Complex Structure

Status: Proven for small graphs (K₃, K₄), scaling to large N = open RG problem

When coupling exceeds a critical value \( K_c \):

A fixed point loses stability.
A Neimark–Sacker (NS) bifurcation creates an invariant 2‑torus \( T^2 \).
This gives an emergent complex structure \( \mathcal{J} \) with \( \mathcal{J}^2 = -\mathbf{1} \).

Conceptually:

\[\mathbb{R} \longrightarrow \mathbb{C}\]

Key scales from simulation:

NS critical bandwidth: \( \Delta\omega^* \approx 1.45 \times 10^{23}\,\text{rad/s} \) (with uncertainty)
Base lattice spacing: \( a_0 \approx 0.08\,\text{fm} \)

Emergent “speed of light”:

\[c \equiv v_{\text{lat}} = a_0 \Delta\omega^\ast\]

Here \( v_{\text{lat}} \) is the lattice maximal propagation speed. In RTG, \( c \) is a derived network constant, not an externally imposed background parameter.

Open task: characterize the RG flow of \( K_c(N) \), \( \omega(\mu) \), \( \Delta\omega(\mu) \) for large graphs.

Phase III – Non-Abelian Lift: Frustration → SU(2) / Quaternions

Status: Conceptually clear, partly proven numerically

Triad frustration:

\[F_\triangle = (\phi_{ij} + \phi_{jk} + \phi_{ki}) \mod 2\pi \neq 0 \]

implies:

No consistent global U(1) phase assignment.
An obstruction that forces a non-Abelian lift to SU(2).

We associate to each coarse region a unit quaternion:

\[q_i(t) \in \mathbb{H} \simeq SU(2) \]

This gives an internal 4‑dimensional algebraic structure:

1 scalar direction (real part)
3 imaginary directions (like \( i, j, k \))

Division-algebra ladder (rungs):

\( k = 0 \): \( \mathbb{R} \) – trivial
\( k = 1 \): \( \mathbb{C} \) – NS bifurcation, complex structure
\( k = 3 \): \( \mathbb{H} \) – triadic frustration, SU(2) regime
\( k = 7 \): \( \mathbb{O} \) – conjectured octonionic high‑energy sector

This ladder underlies RTG’s story about dimensionality and algebra.

Phase IV – Pre-Geometric Structure Tensor and Tetrads

Status: Conceptually solid; definitions now non‑circular

We must build geometry from pre-geometric quantities only, without assuming spacetime coordinates.

4.1 Phase-Geometry Displacement (Internal Indices Only)

For each edge \( \langle ij \rangle \) and internal direction \( a \in \{0,1,2,3\} \), define:

\[\xi_{ij}^{(a)} := \frac{v_{\text{lat}}}{\omega_i} (\phi_j – \phi_i)\,\hat{n}_{ij}^{(a)}\]

where:

\( v_{\text{lat}} = a_0 \Delta\omega^* \) is the emergent lattice velocity.
\( \hat{n}^{(a)}_{ij} \) are four orthogonal internal unit directions, derived from the quaternionic orientation \( q_i \)

(real part and three imaginary axes).

Indices \( a,b \) are internal, not spacetime.

4.2 Pre-Geometric Structure Tensor \( S_{ab} \)

\[S_{ab} = \frac{1}{\mathcal{N}} \sum_{\langle ij \rangle} w_{ij}\, \xi_{ij}^{(a)} \xi_{ij}^{(b)}, \quad w_{ij} = \mathcal{R}_{ij}\]

This is a symmetric \( 4 \times 4 \) tensor in internal index space.

4.3 Eigendecomposition, Density, and Tetrads

\[S_{ab} = \sum_{A=0}^3 \lambda_A\, v^{(A)}_a v^{(A)}_b\]

Let \( \rho(x) \) be the coarse-grained node density (nodes per emergent volume). We tie the tetrad scale to density via a conformal factor:

\[e^A_{\ \mu}(x) = \Omega(x)\,\sqrt{|\lambda_A(x)|}\,v^{(A)}_\mu(x), \quad \Omega(x) \propto \rho(x)^{-1/3}\]

Thus:

Higher node density \( \rho \) → smaller effective length scale.
Lower density → larger length scale.

The conformal factor \( \Omega(x) \) is therefore physically the density-determined scale factor, linking thermodynamics (node density) to geometry (metric size).

At this stage, tetrad indices \( A \) are internal; \( \mu \) will become a spacetime index once the manifold structure is in place (Phase IX).

Phase V – Signature and Dimensionality

Status: Conjectural but structured; clearly marked as such

5.1 Higgs vs Goldstone and “Radial vs Angular” Modes

The NS bifurcation yields:

Radial mode:
- controls amplitude of motion on the torus,
- stiff / unstable direction,
- Higgs-like amplitude mode (massive).
Angular modes:
- motion along the torus,
- soft / marginal directions,
- Goldstone-like phase modes (effectively massless).

In RTG’s interpretation:

radial mode ↦ time-like direction,
angular modes (after SU(2) lifting and ladder structure) ↦ space-like directions.

5.2 Signature from Stability – Conjecture 1

Linearize dynamics around the NS torus with Jacobian \( J \). Then:

Radial eigenvalue:
\[\lambda_0 \approx 1 + \gamma \Delta t, \quad \gamma < 0 \]

Angular eigenvalues:
\[\lambda_{1,2,3} \approx 1 + \alpha_j \Delta t, \quad \alpha_j \approx 0\]

Heuristically:

Radial instability ↦ negative principal eigenvalue in \( S_{ab} \) ↦ time-like direction.
Angular marginality ↦ positive eigenvalues in \( S_{ab} \) ↦ space-like directions.

Conjecture 1 (Signature):

For the k = 3 quaternionic ladder regime: \[\lambda_0 < 0, \quad \lambda_{1,2,3} > 0 ⇒ \eta_{AB} = \mathrm{diag}(-1, +1, +1, +1)\]

This conjecture is to be tested by:

Floquet / normal-form analysis of the NS dynamics,
Direct eigen-analysis of \( S_{ab} \) in RTG simulations.

5.3 From 2D Torus to 3D Space – Conjecture 2

A minimal NS bifurcation (e.g. on K₃) gives a 2D torus \( T^2 \) with two angular directions. RTG needs three spatial dimensions.

Proposed RTG mechanism:

The k = 3 ladder rung (quaternionic regime) provides three independent angular directions via SU(2) generators.
In large frustrated graphs, the pre-geometric structure tensor \( S_{ab} \) generically has rank 4, with one negative and three positive eigenvalues.

Conjecture 2 (3D space):

In the quaternionic/frustrated regime, rank(S_{ab}) = 4 generically, with one negative and three positive principal values, encoding 1 time and 3 space directions.

This is also to be validated numerically by studying the spectrum of \( S_{ab} \) for large graphs.

Phase VI – Metric and Connection

Status: Standard differential geometry, contingent on Phases IV–V

Given:

tetrads \( e^A_{\ \mu} \),
signature \( \eta_{AB} = \mathrm{diag}(-1,+1,+1,+1) \),

we define:

Metric:

\[g_{\mu\nu} = \eta_{AB}\, e^A_{\ \mu} e^B_{\ \nu}\]

Spin connection:

\[A_\mu = q^{-1} \partial_\mu q\]

This is an SU(2) (or, in appropriate representation, SO(3,1)) gauge connection on the emergent manifold.

Phase VII – Torsion: Micro Nonzero, Macro Vanishing via Energy Minimization

Status: Conceptually strong; energetic mechanism specified

At the microscopic lattice level, frustration \( F_{\triangle,i} \) at site \( i \) produces discrete torsion:

\[T^\lambda_{\ \mu\nu}(i) \sim \frac{1}{a_{\text{lat}}^2} \epsilon^{\lambda\mu\nu\rho} F_{\triangle,i,\rho}\]

This is analogous to Einstein–Cartan: torsion couples to spin density.

7.1 Frustration Energy and Macroscopic Torsion

Instead of relying on “random cancellation”, RTG uses an energetic argument:

Define a coarse-grained torsion field \( \bar T^\lambda_{\ \mu\nu}(x) \).

Define a frustration energy functional:
\[E_{\text{frust}} \propto \int (\bar T^\lambda_{\ \mu\nu} \bar T_\lambda^{\ \mu\nu})\, dV\]

The network relaxes dynamically to minimize \( E_{\text{frust}} \).

The macroscopic state with \( \bar T = 0 \) is the ground state.
Any nonzero large-scale torsion costs energy proportional to volume and is suppressed.

Thus:

Microscale: torsion is real and important (spin, particle structure, mass gap).
Macroscale: the energy-minimizing configuration is torsion-free, i.e. the Levi–Civita connection.

Phase VIII – Holonomy and Curvature

Status: Standard once connection exists

Given a spin connection \( A_\mu \):

Holonomy around a loop:

H(\partial P) = \mathcal{P} \exp\left(\oint_{\partial P} A_\mu dx^\mu\right)

Curvature:

R_{\mu\nu} = \partial_\mu A_\nu – \partial_\nu A_\mu + [A_\mu, A_\nu]

In tetrad indices, this yields \( R^{AB}_{\ \ \mu\nu} \). We can define observables such as a “holonomy gap” (spread of \( \mathrm{Tr}(H) \) over loops) as a diagnostic of curvature and torsion fluctuations.

Phase IX – Continuum Manifold as Inverse Limit

Status: Mathematically standard framework; convergence conditions to be tested numerically

RTG defines the continuum spacetime manifold \( \mathcal{M} \) as the inverse limit of refining graphs:

\mathcal{M} = \varprojlim (G_0 \leftarrow G_1 \leftarrow G_2 \leftarrow \cdots)

Graphs \( G_n \) have lattice spacing \( a_n = a_0 / 2^n \).
Each refinement step splits nodes into subnodes with consistency conditions.

Convergence conditions (schematic):

Frequency conservation under refinement:

(1 / 2^d) \sum_{j \in \text{children}(i)} \omega_j^{(n+1)}
=
\omega_i^{(n)} + O(a_n^2)

Curvature bounded:

\sup_n \|R_{\mu\nu\rho\sigma}(G_n)\|_{L^\infty} < \infty

Sobolev regularity:

The fields (like \( \phi^{(n)} \)) satisfy regularity conditions so that derivatives exist in the limit.

If these hold, the inverse limit \( \mathcal{M} = \varprojlim G_n \) exists and carries a smooth differential structure. Numerically, one checks convergence by simulating at \( a_0, a_0/2, a_0/4 \) and looking for stable proton mass, binding energy, and curvature.

Phase X – Low-Energy Gravity: Einstein–Hilbert Dominant

Status: Effective field theory logic, widely accepted

Once \( (\mathcal{M}, g_{\mu\nu}) \) and a Levi–Civita connection exist at large scales, the effective action can be written as:

S_{\text{eff}} = \int d^4x\,\sqrt{-g}\, \left[ \frac{1}{16\pi G_0}R – \Lambda_0 + \alpha_1 R^2 + \alpha_2 R_{\mu\nu}R^{\mu\nu} + \beta_1 T^2 + \cdots \right]

RTG’s claim:

For energies \( E \ll \hbar \Delta\omega^* \sim 10\,\text{GeV} \), the Einstein–Hilbert term \( R \) is the dominant contribution.
Higher-curvature and torsion terms are suppressed by powers of the UV scale (related to \( \Delta\omega^* \) or Planck-like scales).

Thus, GR is the IR limit of RTG.

Phase XI – Quantum RTG (Sketch)

Status: Programmatic, not yet fully developed

To include quantum effects, RTG promotes node variables to operators on a Hilbert space.

Define a Hamiltonian \( H \) reflecting the sinusoidal couplings (Kuramoto-like terms) at the quantum level.

Define a graph-based path integral or partition function:

Z = \int \mathcal{D}[\text{graphs}, \phi_i(t)]\, e^{i S_{\text{nodes}}/\hbar}

In this picture:

NS bifurcations and frustration become nontrivial saddle points / instantons.
They contribute to mass gaps and possible torsion anomalies at quantum level.
“Quantum gravity” in RTG lives on top of the emergent classical GR background created in Phases I–X.

Phase XII – Phenomenology and the RTG Radion

Status: Predictions and targets

The radial NS mode is a scalar controlling the amplitude (scale) of the emergent geometry.
A characteristic mass scale is:

m_{\text{radial}} \sim \hbar \Delta\omega^*/c^2 \sim \mathcal{O}(10\,\text{GeV})

We name this:

RTG Radion: the scalar mode that controls the overall scale of the emergent geometry (analogous to a radion/dilaton in extra-dimensional theories).

It couples to the trace of the energy–momentum tensor.
It is distinct from the Standard Model Higgs, though mixing is not forbidden in principle.
It provides a concrete phenomenological target: a geometric scalar in the ~10–100 GeV range.

Other possible phenomenological signatures:

Small corrections to proton charge radius (via micro torsion effects)
Holonomy gap effects in strong-gravity or high-density regimes
Subtle cosmological signatures in CMB phase statistics or high-energy spectra

Phase XIII – What RTG Explains vs What GR Assumes

Feature	GR: usually…	RTG: here…
Spacetime manifold	Assumed as a background	Emerges as inverse limit of graphs
Lorentzian signature	Postulated	Conjecturally derived from NS stability and structure tensor spectrum
Metric \( g_{\mu\nu} \)	Fundamental field	Derived from tetrads built from \( S_{ab} \)
Tetrads / frames	Auxiliary or postulated	Primary geometric object in RTG
Connection (Levi–Civita)	Imposed by setting torsion = 0	Ground state of frustration energy (macro torsion vanishes dynamically)
Spin–torsion coupling	Optional via Einstein–Cartan	Built-in via microscopic frustration and torsion
Cosmological constant	Ad hoc constant (fine-tuning)	Scale-dependent via RG flow of the network
Quantum gravity	External quantization of GR	Emerges from quantized node dynamics and graph path integrals

Phase XIV – Final Pipeline Summary (v2.2)

Phase I (Micro): (ω_i, φ_i, s_i), R_ij ⇒ (K > K_c) ⇒ NS Bifurcation (T²) Phase II (Algebraic): ℝ → ℂ F_Δ ≠ 0 ⇒ SU(2), q_i ∈ ℍ Phase III (Pre-Geometry): ξ_{ij}^{(a)} ⇒ S_{ab} ⇒ {λ_A, v^(A)} ⇒ e^A_μ(ρ) Phase IV (Signature/Torsion): NS stability ⇒ Conjecture η_{AB} = (-,+,+,+) F_Δ ⇒ T_micro, E_frust ∝ ∫ T² ⇒ T_macro = 0 Phase V (Continuum/Gravity): lim← G_n ⇒ (M, g_{μν}) A_μ ⇒ R^{AB}_{ μν} ⇒ S_EH + corrections Phase VI (Quantum/Phenomenology): Z[graphs] ⇒ quantum GR corrections RTG Radion (m ~ 10 GeV), plus other signals

This completes the RTG → Geometry → GR Wrap-Up v2.2, capturing the current conceptual structure, the solid parts, and the conjectural parts with clear test programs, ready to be distilled into Axiom Set v2.0.