Multi-tracers, multi-surveys: a joint Fisher analysis of DESI+PFS

Abstract

Marginalizing over roughly 12 effective-field-theory (EFT) nuisance parameters per tracer per redshift bin is a dominant systematic cost in full-shape galaxy power spectrum analyses. Simulation-based priors (SBP) tighten these parameters but rely on N-body simulations and halo-occupation-distribution (HOD) models. We propose a multi-tracer Fisher analysis as a model-independent alternative: cross-spectra between galaxy populations calibrate EFT bias and stochastic parameters from data alone, through two channels -- within a survey and across overlapping surveys -- combined in a volume-partitioned joint Fisher. We forecast across the 14,000\;deg2 Dark Energy Spectroscopic Instrument (DESI) footprint, including the \!1,200\;deg2 Prime Focus Spectrograph (PFS) overlap at z∈[0.6,1.6] with up to 4 tracers (PFS-ELG, DESI-ELG, DESI-LRG, DESI-QSO). The internal-DESI channel (LRG, ELG, and QSO over the full footprint) provides most of the gain, improving σ(fσ8) by 33%, σ(M) by 80%, and σ(m) by 49% over a single-tracer broad-prior baseline at k max=0.20\,h\,Mpc-1. Adding the PFS\,×\,DESI overlap further tightens these by 9%, 24%, and 9%, respectively, after marginalizing over residual cross-population stochasticity. A parameter-importance decomposition shows that the dominant driver is calibration of the b1σ8 prior, tightened from a flat prior to σ≈ 0.13, which breaks the b1σ8--fσ8 degeneracy of single-tracer analyses. The multi-tracer multi-survey approach targets the same b1 calibration as SBPs, using observed cross-spectra rather than HOD mocks as a model-independent check on SBP-driven b1σ8 shifts. The framework extends to any number of overlapping spectroscopic surveys.