theorem
proved
C_proj_value
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IndisputableMonolith.Gravity.CoerciveProjection on GitHub at line 60.
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57 This bounds the operator norm of the ILG projection kernel. -/
58def C_proj : ℚ := 2
59
60theorem C_proj_value : C_proj = 2 := rfl
61
62/-- The defect bound: Defect(Phi) <= M * K_net * C_proj * sup T_W[Phi].
63 The constant M * K_net * C_proj controls the stability of the energy minimizer. -/
64def defect_bound_constant : ℚ := K_net * C_proj
65
66theorem defect_bound_constant_value :
67 defect_bound_constant = 162 / 49 := by
68 unfold defect_bound_constant K_net C_proj; norm_num
69
70/-! ## Pressure Equivalence -/
71
72/-- The ILG modified Poisson equation is EQUIVALENT to the standard Poisson
73 equation with an effective pressure source:
74
75 ILG: nabla^2 Phi = 4*pi*G * a^2 * (w * rho_b * delta_b)
76 Standard: nabla^2 Phi = 4*pi*G * a^2 * p
77
78 where p = w * rho_b * delta_b is the "effective pressure."
79
80 This equivalence means ILG is NOT a modification of GR's field equations
81 but rather a modification of the SOURCE SIDE only. -/
82structure PressureEquivalence where
83 w_kernel : ℝ → ℝ
84 rho_b : ℝ → ℝ
85 delta_b : ℝ → ℝ
86 effective_pressure : ℝ → ℝ
87 equiv : ∀ x, effective_pressure x = w_kernel x * rho_b x * delta_b x
88
89/-- Any ILG kernel with w >= 1 defines a valid pressure equivalence. -/
90theorem pressure_equiv_from_w (w rho delta : ℝ → ℝ) :