Fewer simulations, sharper covariances: Reducing mock covariance noise with Zeldovich approximation control variates

Abstract

We present a control-variate method for reducing the variance of power spectrum covariance matrix estimates from simulations of large-scale structure. The key idea is to pair each mock simulation with a cheap Zeldovich-approximation realization sharing the same initial conditions, and to use the known statistical properties of the Zeldovich field to remove correlated sample variance from the covariance estimator. Under a Gaussian disconnected approximation, we derive fully analytic expressions for both the optimal control-variate coefficient, β(k,;k','), and the corresponding correlation, ρ(k,;k','), in terms of the auto- and cross-power spectra of the target and control fields. In the monopole case, the correlation takes the particularly simple form ρ(k,k') = r2(k),r2(k'), where r(k) is the standard cross-correlation coefficient between the target and Zeldovich fields, implying that covariance estimation remains highly efficient whenever the two fields are strongly correlated. For masked redshift-space lognormal mocks, resembling Luminous Red Galaxies from the Dark Energy Spectroscopic Instrument (DESI), we find that the control-variate estimator reduces the variance of the covariance matrix by approximately an order of magnitude on large scales, k 0.05\,h\, Mpc-1, precisely where accurate covariance estimation is most challenging. The gains are smaller for higher k but typically accelerate convergence by a factor of 2-3, substantially lowering the computational cost of covariance estimation for current and upcoming large-scale structure surveys. Due to its simplicity, this method is readily implementable in current imaging and spectroscopic surveys (e.g., DESI, Euclid, LSST, PFS, SPHEREx).