Sampling Artifact in Volume Weighted Velocity Measurement.--- II. Detection in simulations and comparison with theoretical modelling

Abstract

Measuring the volume weighted velocity power spectrum suffers from a severe systematic error, due to imperfect sampling of the velocity field from inhomogeneous distribution of dark matter particles/halos in simulations or galaxies with velocity measurement. This "sampling artifact" depends on both the mean particle number density nP and the intrinsic large scale structure (LSS) fluctuation in the particle distribution. (1) We report robust detection of this sampling artifact in N-body simulations. It causes 12% underestimation of the velocity power spectrum at k=0.1h/Mpc for samples with nP=6×10-3 (Mpc/h)-3. This systematic underestimation increases with decreasing nP and increasing k. Its dependence on the intrinsic LSS fluctuations is also robustly detected. (2) All these findings are expected by our theoretical modelling in paper I Zhang14. In particular, the leading order theoretical approximation agrees quantitatively well with simulation result for nP6× 10-4(Mpc/h)-3. Furthermore, we provide an ansatz to take high order terms into account. It improves the model accuracy to 1% at k0.1h/Mpc over 3 orders of magnitude in nP and over typical LSS clustering from z=0 to z=2. (3) The sampling artifact is determined by the deflection D field, which is straightforwardly available in both simulations and data of galaxy velocity. Hence the sampling artifact in the velocity power spectrum measurement can be self-calibrated within our framework. By applying such self-calibration in simulations, it becomes promising to determine the real large scale velocity bias of 1013M halos with 1% accuracy, and that of lower mass halos by better accuracy. ...[abridged]