Regression on Regression: Mapping Data-Driven Binary Black Hole Merger Rate Fits to Progenitor Histories

Abstract

The binary black hole (BBH) merger rate is governed by the progenitor formation rate and the distribution of delay-times between formation and merger, but these functions remain poorly constrained. We introduce a framework that maps the parameters of physics-driven models directly onto existing data-driven fits of the BBH merger rate. This ``regression on regression'' approach enables physical interpretation of flexible population models without the computational burden of reanalyzing the underlying gravitational-wave event data. Applying this method to the B-Spline merger-rate posteriors from the Fourth Gravitational-Wave Transient Catalog, we fit the minimum delay time (τmin), delay-time power-law index (α), and progenitor formation parameters controlling the normalization (A), early-time growth (γ), and late-time decay (δ). Increasing the number of anchoring redshift points from two to four reduces the median sum-squared error (SSE) by a factor of ≈ 4.5. However, residuals reveal that the physical model does not pass through all four anchors, exposing model misspecification and demonstrating a key strength of the framework: unlike standard inference methods, which preferentially weight compatible curves and mask underlying tensions, our approach exposes BBH posteriors irreconcilable with the model. Despite uncertainties at z1, the shape of the progenitor formation rate at low-z is robust and evolves more steeply than the global star formation rate (SFR), supporting a preference for low metallicity environments. Specifically, the log-space slope of the progenitor rate is ≈ 5.3 times steeper than the SFR between z=0.1 and z=1.0. Ultimately, a more complex phenomenological model is required to match the B-Spline merger rates.