Gravitational-wave measurements of the mass and angular momentum of a black hole

A deformed black hole produced in a cataclysmic astrophysical event should undergo damped vibrations which emit gravitational radiation. By fitting the observed gravitational waveform h (t) to the waveform predicted for black-hole vibrations, it should be possible to deduce the hole's mass M and dimensionless rotation parameter a= (c/G) (angular momentum) /M^2. This paper estimates the accuracy with which M and a can be determined by optimal signal processing of data from laser-interferometer gravitational-wave detectors. It is assumed that the detector noise has a white spectrum and has been made Gaussian by cross correlation of detectors at different sites. Assuming, also, that only the most slowly damped mode (which has spheroidal harmonic indices l=m=2) is significantly excited---as probably will be the case for a hole formed by the coalescence of a neutron-star binary or a black-hole binary---it is found that the one-sigma uncertainties in M and a are /M2. 2^-1 (1-a) ^0. 45, 5. 9^-1 (1-a) ^1. 06, where hₒ (S₇) ^-1/2 (1-a) ^-0. 22. Here is the amplitude signal-to-noise ratio at the output of the optimal filter, hₒ is the wave's amplitude at the beginning of the vibrations, f is the wave's frequency (the angular frequency divided by 2), and S₇ is the frequency-independent spectral density of the detectors' noise. These formulas for and are valid only for 10. Corrections to these approximate formulas are given in Table II.