Finite-Window Centered Organization of Neighboring Poles

Abstract

Near-degenerate resonance poles arise widely in open-wave systems. For gravitational-wave ringdowns, inference is performed on finite time windows where neighboring quasinormal modes can be spectrally close; the waveform is then dominated by a common carrier with a slowly varying interference envelope, while representing the signal as a sum of two independently resolved damped exponentials e-ω t becomes numerically ill-conditioned when the dimensionless splitting η=|σ|Teff is small. We give a finite-window organizing principle for such neighboring-pole sectors: the local two-pole singular block of the Green-function integrand is rewritten exactly about a shared carrier ωc and half-splitting σ, and for |σ t| 1 the time-domain projection is systematically a carrier plus a first-jet piece t\,e-ωc t, without requiring a literal double pole or exceptional-point merger in parameter space. The centered first-jet basis has O(1) Gram conditioning, whereas the resolved-mode basis satisfies cond(Gres) 12\,η-2 as η 0 (transparent real-splitting slice). We supply finite-window diagnostics in which marks when the jet correction must be retained and η2 sets the residual error scale once it is retained. Minimal two-pole numerics verify the scaling. For Kerr black holes we fix one adjacent-overtone mode pair (catalog label pair45; shared (l,m) and consecutive overtones in our indexed tabulation), scan spin a∈[0.8770,0.8810], and adopt the spectral window proxy Tspec=β/|ωc| with β=2.0 to illustrate the same conditioning contrast in a near-degenerate sector.