English

A data-analysis driven comparison of analytic and numerical coalescing binary waveforms: nonspinning case

General Relativity and Quantum Cosmology 2008-11-26 v2

Abstract

We compare waveforms obtained by numerically evolving nonspinning binary black holes to post-Newtonian (PN) template families currently used in the search for gravitational waves by ground-based detectors. We find that the time-domain 3.5PN template family, which includes the inspiral phase, has fitting factors (FFs) >= 0.96 for binary systems with total mass M = 10 ~ 20 Msun. The time-domain 3.5PN effective-one-body template family, which includes the inspiral, merger and ring-down phases, gives satisfactory signal-matching performance with FFs >= 0.96 for binary systems with total mass M = 10 ~ 120 Msun. If we introduce a cutoff frequency properly adjusted to the final black-hole ring-down frequency, we find that the frequency-domain stationary-phase-approximated template family at 3.5PN order has FFs >= 0.96 for binary systems with total mass M = 10 ~ 20 Msun. However, to obtain high matching performances for larger binary masses, we need to either extend this family to unphysical regions of the parameter space or introduce a 4PN order coefficient in the frequency-domain GW phase. Finally, we find that the phenomenological Buonanno-Chen-Vallisneri family has FFs >= 0.97 with total mass M=10 ~ 120Msun. The main analyses use the noise spectral-density of LIGO, but several tests are extended to VIRGO and advanced LIGO noise-spectral densities.

Cite

@article{arxiv.0704.1964,
  title  = {A data-analysis driven comparison of analytic and numerical coalescing binary waveforms: nonspinning case},
  author = {Yi Pan and Alessandra Buonanno and John G. Baker and Joan Centrella and Bernard J. Kelly and Sean T. McWilliams and Frans Pretorius and James R. van Meter},
  journal= {arXiv preprint arXiv:0704.1964},
  year   = {2008}
}

Comments

19 pages, 17 figures, added references, corrected typos, changed figure 16