Quantitative local recovery of Kerr-de Sitter parameters from high-frequency equatorial quasinormal modes

Abstract

We study an inverse resonance problem for the scalar wave equation on the Kerr-de Sitter family. In a compact subextremal slow-rotation regime and at a fixed overtone index, high-frequency quasinormal modes admit semiclassical quantization and a real-analytic labeling by angular momentum indices. Using this structure, we first prove that a finite equatorial high-frequency package of quasinormal-mode frequencies determines the mass and rotation parameter (M,a) (for fixed cosmological constant >0), with a quantitative stability estimate. As a key geometric input we compute explicit second-order (in a) corrections to the equatorial photon-orbit invariants which control the leading real and imaginary parts of the quasinormal modes. Finally, allowing to vary in a compact interval, we show that adding one damping observable (the scaled imaginary part of a single equatorial mode) yields a three-parameter inverse theorem: a finite package of three independent real observables determines (M,a,) locally in the slow-rotation regime away from a=0.