Timescale Coalescence Makes Hidden Persistent Forcing Spectrally Dark
Abstract
Under coarse observation, unresolved slow forcing can remain dynamically active yet locally invisible to reduced spectral inference. For a solvable driven AR(1) benchmark, the local Whittle/Kullback--Leibler distance from the true spectrum to the best nearby one-pole surrogate obeys (λ)=Cλ4+O(λ6), even though the observed spectrum itself is perturbed at O(λ2). The quartic onset is a geometric consequence of the reduced model manifold: the O(λ2) perturbation is partially absorbed by tangent-space reparametrization, and only the normal residual survives. We obtain C in closed form for an AR(1) hidden driver and show that C vanishes as (a-b)2 at timescale coalescence, identifying a spectrally dark regime. We then show that this dark regime is not geometrically inevitable: for a non-degenerate AR(2) hidden driver (second characteristic root z2≠ 0), C>0 for all parameter values, including single-root coalescence, because the richer spectral structure cannot be absorbed by the two-dimensional tangent space. The quartic coefficient interpolates smoothly between the two cases as C z24 when the second characteristic root vanishes. Together, the AR(1) and AR(2) results yield a classification within the one-pole projection class: the quartic law and the boundary (N)( N/N)1/4 are universal features of the projection geometry within this class, while the dark regime requires the hidden driver's spectrum to match the null family's pole structure.
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