Journal
PHYSICAL REVIEW D
Volume 87, Issue 2, Pages -Publisher
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevD.87.024004
Keywords
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Funding
- National Research Foundation
- Korean Government [NRF-2011-220-C00029]
- Global Science Experimental Data Hub Center (GSDC) at KISTI
- BAERI Nuclear R & D program of MEST/KOSEF [M20808740002]
- Research Corporation for Scientific Advancement
- WVEPSCoR Research Challenge Grant
- NSF [PHY-0970074]
- Bradley Program Fellowship
- UWM Research Growth Initiative
- Division Of Physics
- Direct For Mathematical & Physical Scien [0970074] Funding Source: National Science Foundation
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Inspiralling black hole-neutron star binaries emit a complicated gravitational wave signature, produced by multiple harmonics sourced by their strong local gravitational field and further modulated by the orbital plane's precession. Some features of this complex signal are easily accessible to ground-based interferometers (e.g., the rate of change of frequency), others less so (e.g., the polarization content), and others still are unavailable (e.g., features of the signal out of band). For this reason, an ambiguity function (a diagnostic of dissimilarity) between two such signals varies on many parameter scales and ranges. In this paper, we present a method for computing an approximate, effective Fisher matrix from variations in the ambiguity function on physically pertinent scales which depend on the relevant signal-to-noise ratio. As a concrete example, we explore how higher harmonics improve parameter measurement accuracy. As previous studies suggest, for our fiducial black hole-neutron star binaries and for plausible signal amplitudes, we see that higher harmonics at best marginally improve our ability to measure parameters. For nonprecessing binaries, these Fisher matrices separate into intrinsic (mass, spin) and extrinsic (geometrical) parameters; higher harmonics principally improve our knowledge about the line of sight. For the precessing binaries, the extra information provided by higher harmonics is distributed across several parameters. We provide concrete estimates for measurement accuracy, using coordinates adapted to the precession cone in the detector's sensitive band. DOI: 10.1103/PhysRevD.87.024004
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