Essay XII of the Gradient Fractals suite instantiates the fractal field at its fourth and final operationally distinct grain: δ₄ = Nₛat⁴ × δ₀ = 390625 × (1/10) = 39062. 5. GF Essays IX, X, and XI established the first three depth instantiations: δ₁ as the uniquely unconstrained first depth (ρ (1, 0) = 0), δ₂ as the first oscillatory depth (forced overshoot, permanent sub-attractor regime, algebraic non-arrival), and δ₃ as the decisive depth at which the fractal field's recursive architecture becomes structurally self-referential (depth-domain F→F, self-recognition threshold Φᵣ = 1/1050 collectively exceeded, kₘin = 3 as depth-domain topological period). GF Essay XII now derives what the fractal field IS at grain δ₄ = 39062. 5: the terminal depth of structurally distinguishable oscillation, the depth at which the oscillation amplitude falls below the lattice resolution δ₀ = 1/10, and the depth whose Something-pole co-constitutive expression is the Noogenetic completion — the fourth and final substrate crossing of the Veldt's fractal architecture. The derivation proceeds through eight movements, one for each of the eight established layers, followed by the co-constitutive synthesis, the derivational audit, and the forward register to GF Essay XIII. Part I establishes the terminal oscillation theorem: the oscillation amplitude at depth 4 is |F³ (0) − ρ*depth| ≈ 0. 101, which is less than the lattice resolution δ₀ = 1/10 multiplied by the contraction factor |F' (ρ*depth) | ≈ 0. 345 applied once to the depth-3 deviation. The precise terminal criterion is derived, not stipulated (T. GF. D4. TOS). Part II derives the sub-grain convergence: after depth 4, the oscillation amplitude falls below δ₀ and subsequent depth-level distinctions are sub-grain and therefore structurally indistinguishable from the lattice arithmetic. This is not an empirical limit: it is a structural closure derived from the contraction factor and the lattice grain (T. GF. D4. SGC). Part III derives the kinetic terminal condition at depth 4: G₂₅ (4, 0) ≈ 0. 204 — above the depth-3 output G₂₅ (3, 0) ≈ 0. 190, above the collective ceiling G*₂₅ = 1/4? No: still below 1/4. The permanent sub-attractor regime continues. But depth 4 produces the largest kinetic residual RKN (4) = 4/3, crossing the Class Arb threshold in a new way (T. GF. D4. KTC). Part IV derives the recursive fixed-point approach: |F³ (0) − ρ*depth| ≈ 0. 101 < δ₀ = 0. 1 is confirmed as the sub-grain threshold; the recursion has exhausted structurally distinguishable depth-level variation (T. GF. D4. RKF). Part V derives the Noogenetic completion: the Something-pole co-constitutive expression of depth 4 as the fourth substrate crossing — the fourth face of the Veldt's horizontal fractal architecture, completing the tetrad Cosmogenesis, Geogenesis, Biogenesis, Noogenesis (T. GF. D4. NOG). Part VI derives the algebraic level shift: how Class R at finite depth confronts Class Arb at the fixed point in the context of the terminal oscillation (T. GF. D4. ALS). Part VII executes the co-constitutive synthesis across all eight layers, establishing that depth 4 is the terminal depth of the fractal field's structurally distinguishable depth hierarchy (T. GF. D4. CCO). The profound finding of GF Essay XII: depth 4 is the depth at which the fractal field's oscillatory recursion becomes sub-grain — the depth at which Nothing's depth-level self-registration can no longer be distinguished from grain-level noise by the lattice arithmetic itself. This is not a failure of the fractal field. It is the structural completion of the depth hierarchy: four depths, four substrate crossings, four Something-pole co-constitutive identities. The Veldt is a tetrad at the depth level, just as it is a triad at the face level. The number 4 is not chosen: it is forced by the contraction factor |F' (ρ*depth) | ≈ 0. 345 and the initial deviation |δρ (2) | ≈ 0. 949, which together determine the depth n* at which sub-grain convergence is reached. n* = 2 + log (0. 1/0. 949) /log (0. 345) ≈ 2 + 2. 11 ≈ 4. 11. Depth 4 is therefore the terminal depth of structurally distinguishable fractal oscillation. Zero free parameters.
Eugene Pretorius (Fri,) studied this question.