Active Thermography (pulsed / lock-in IR inspection) L1-115

Industrial InspectionThermal-diffusion non-destructive imagingδ=3 · standardL_DAG = 3📋 Stub — not mineable

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Unclaimed Principle — open for contribution

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Forward model E

T (x, y, t) = T_{b} g + so l v e [h e a t_{e} q n w i t h so u r ce (x, y, 0) an d b o u n d a r y co n d]; d e f ec t d e pt h v ia p ha seco n t r a s t

Active Thermography (pulsed / lock-in IR inspection): active thermography ir produces the measurement through a 4-node primitive DAG L.heat_source -> L.thermal_diffusion -> D.ir_camera -> int.temporal, with time-integrated exposure and additive Gaussian thermal/electronic noise. Recovery is posed as a non-convex inverse problem that inverts the forward operator to estimate the scene-side 3D defect depth map. Difficulty tier delta=3 with effective condition number kappa_eff~12; calibration-level mismatch (emissivity_variation, surface_reflections, ambient_thermal_load) sets the accuracy floor at the Omega boundary. See the forward_model field for the closed-form imaging equation.

L-DAG

L.heat_source -> L.thermal_diffusion -> D.ir_camera -> int.temporal

L.heat_sourceL.thermal_diffusionD.ir_cameraint.temporal

Well-posedness W

Existence:: true
Uniqueness:: true
Stability:: conditional
κ:: 240

Existence of the recovered 3D defect depth map is guaranteed within the declared Omega bounds. Uniqueness is local rather than global (non-convex landscape); convergence depends on initialisation and priors. Stability is moderately conditioned (kappa_eff ~= 12); emissivity_variation dominates the stability cliff; surface_reflections and the remaining mismatch parameters contribute higher-order bias terms. Additive gaussian thermal/electronic noise sets the irreducible data-fidelity floor, while mild Tikhonov or analytic inversion is sufficient at the nominal Omega point.

Solvability C

Solver class:: linear-operator + convex optimisation [Phase-Lockin, PPT-Thermography] | linear-operator + deep neural prior [ThermoNet]
Convergence rate q:: 2
Complexity:: O(H * W * log(...)) per iteration; learned variants: O(H W Z * F_theta_cost) per forward pass

Specs (0)

No L2 specs registered yet for this principle.