Rain Rate Estimation Bounds and Weather-Adaptive Pilot Allocation for LEO Satellite ISAC

Abstract

Rain attenuates Ku-band satellite signals by up to 20~dB, encoding precipitation information along the Earth-space slant path. This paper derives the Bayesian Cram\'er-Rao bound (BCRB) for rain rate estimation from LEO broadband OFDM downlinks. Using corrected ITU-R P.838-3 coefficients, the standard CRB yields a minimum detectable rain rate R ≈ 4.3 for a single link at the 38 reference elevation. We derive the prior Fisher information in closed form for log-normal rain (cv = 1.05, from 186,292 samples) and show that a single-snapshot BCRB reduces R to 1.1; exploiting temporal correlation ( = 0.95) over a 30-min window further tightens it to 0.95, while multi-link fusion across N = 215 links lowers the operating-point RMSE lower bound at R = 20 to approximately 0.07. Building on these bounds, we formulate a weather-adaptive pilot allocation that minimizes the BCRB subject to a hard spectral-efficiency constraint, characterize its three-regime structure (full-sensing, throughput-tracking, outage), and pair it with a CUSUM rain onset detector achieving sub-10-min delay for R ≥ 20. A closed-form analysis of dynamic LEO slant geometry identifies a sensing-optimal elevation at the P.618-validity floor of 15 that yields a 1.58× geometric improvement over the 38 baseline, exposing a structural anti-correlation between sensing- and communication-optimal elevations along an orbital pass. Validation against 9.4~million radar samples from 215 Ku-band GEO satellite links (r = 0.72, RMSE~= 1.24) and 113 rain gauges confirms the underlying attenuation model; the bounds transfer to LEO constellations under matched OFDM signal parameters, with dedicated LEO validation left for future work.