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Literature Catalog: Data Analysis: Compact Binary Inspiral
Also sorted by
date
Last updated June 19, 2002.
B. Allen et al,
Observational Limit on Gravitational Waves from Binary
Neutron Stars in the Galaxy, Phys. Rev. Lett. 83, 1498, (1999).
R. Balasubramanian, B.S . Sathyaprakash and S. V. Dhurandhar,
Estimation of parameters of gravitational waves from coalescing binaries,
Pramana 45, L436-L470, (1995).
R. Balasubramanian, B.S . Sathyaprakash and S. V. Dhurandhar,
Gravitational waves from coalescing binaries: detection strategies and
Monte Carlo estimation of parameters, Phys. Rev. D53, 3033-3055, (1995);
Erratum-ibid. D54, 1860, (1996).
S. Bose, A. Pai and S. Dhurandhar,
Detection of Gravitational Waves from
Inspiraling, Compact Binaries Using a Network of Interferometric
Detectors, Int. J. Mod. Phys. D 9, 325-329, (2000).
S. Bose,
A robust and coherent network statistic for detecting
gravitational waves from inspiralling compact binaries in non-Gaussian
noise, Class. Quantum Grav. 19, 1437-1442, (2002).
P. R. Charlton et al,
A method for the detection of gravitational waves
from inspiralling compact binaries using a fast chirp transform, Class.
Quantum Grav. 19, 1493-1498, (2002).
N. Christensen and R. Meyer, Using Markov chain Monte Carlo
methods for estimating parameters with gravitational radiation data, Phys .Rev.
D64, 022001, (2001).
R. P. Croce et al,
Gravitational Wave Chirp Search: Economization of PN Matched Filter Bank via
Cardinal Interpolation, Phys. Rev. D62, 121101, (2000).
C. Cutler et al, The Last
Three Minutes: Issues in Gravitational Wave Measurements of Coalescing Compact
Binaries, Phys. Rev. Lett. 70, 2984-2987, (1993).
C. Cutler and E. Flanagan,
Gravitational Waves from Mergin Compact Binaries: How Accurately Can One Extract
the Binary's Parameters from the Inspiral Waveform?, Phys. Rev. D49, 2658-2697,
(1994).
T. Damour, B. R. Iyer and B. S. Sathyaprakash, Improved filters for
gravitational waves from inspiralling compact binaries, Phys. Rev. D57,
885-907, (1998).
T. Damour, B. R. Iyer and B. S. Sathyaprakash, Modelling Gravitational Waves from
Inspiralling Compact Binaries in "Second Edoardo Amaldi Conference on
Gravitational Waves" (1998).
T. Damour, B. R. Iyer and B. S. Sathyaprakash, Frequency-domain P-approximant
filters for time-truncated inspiral gravitational wave signals from compact
binaries, Phys. Rev. D62, 084036, (2000).
T. Damour, B. R. Iyer and B. S. Sathyaprakash, A Comparison of search
templates for gravitational waves from binary inspiral, Phys. Rev. D63, 044023,
(2001).
T. Damour, B. R. Iyer and B. S. Sathyaprakash, Detecting Binary Black Holes With
Efficient and Reliable Templates
L. S. Finn, Observing Binary
Inspiral with LIGO
L. S. Finn, Binary inspiral,
gravitational radiation, and cosmology, Phys. Rev. D53, 2878-2894, (1996).
L. S. Finn and D. F. Chernoff, Observing binary inspiral in
gravitational radiation: One interferometer, Phys. Rev. D47, 2198-2219, (1993).
L. S. Finn and D. F. Chernoff,
Gravitational Radiation, Inspiraling Binaries, and Cosmology, Astrophys.J. 411,
L5-L8, (1993).
L. S. Finn and K. S. Thorne, Gravitational Waves from a
Compact Star in a Circular, Inspiral Orbit, in the Equatorial Plane of a Massive,
Spinning Black Hole, as Observed by LISA, Phys. Rev. D62, 124021, (2000).
S. A. Hughes, Gravitational waves from
extreme mass ratio inspirals: Challenges in mapping the spacetime of massive,
compact objects, Class. Quantum Grav. 18, 4067-4074, (2001).
B. J. Owen and B. S. Sathyaprakash, Matched filtering of
gravitational waves from inspiraling compact binaries: Computational cost and
template placement, Phys. Rev. D60, 022002, (1999).
A. Pai, S. Dhurandhar and S. Bose, A data-analysis strategy for
detecting gravitational-wave signals from inspiraling compact binaries with a
network of laser-interferometric detectors, Phys. Rev. D64, 042004, (2001).
A. Pai, S. Bose and S. Dhurandhar,
Computational cost for detecting inspiraling binaries using a network of laser
interferometric detectors, Class. Quantum Grav. 19, 1477-1484, (2002).
V. Pierro et al, Fast and Accurate
Computation Tools for Gravitational Waveforms from Binary Sistems with any Orbital
Eccentricity, Mon. Not. Roy.Astron. Soc. 325, 358 (2001).
B. S. Sathyaprakash, Mother templates
for gravitational wave chirps, Class.Quantum Grav. 17, L157-162, (2000).
A. S. Sengupta, S. V. Dhurandhar, A. Lazzarini and T. Prince, Extended hierarchical search (EHS)
algorithm for detection of gravitational waves from inspiraling compact
binaries, Class. Quantum Grav. 19, 1507-1512, (2002).
A. M. Sintes and A. Vecchio,
Detection of gravitational waves from inspiraling compact binaries using
non-restricted post-Newtonian approximations, in "Rencontres de Moriond 1999,
Gravitational Waves and Experimental Gravity", Eds. Van et al, World Publishers,
Hanoi - Vietnam, (2000).
A. M. Sintes and A. Vecchio, LISA
observations of massive black holes binaries using post-Newtonian wave-forms,
in "Gravitational Waves: Third Edoardo Amaldi Conference, Pasadena, California,
12-16 July, 1999", Ed. S. Meshkov, American Institute of Physics, Melville
NY,403-404, (2000).
H. Tagoshi et al, Searching
for Gravitational Waves from Inspiraling Compact Binaries Using TAMA300 Data,
Int. J. Mod. Phys. D 9, 319-323, (2000).
H. Tagoshi et al, The First
Search for Gravitational Waves from Inspiraling Compact Binaries using TAMA300
data, Phys. Rev. D63, 062001, (2001).
W. Tichy, E. E. Flanagan and E. Poisson, Can the post-Newtonian
gravitational waveform of an inspiraling binary be improved by solving the energy
balance equation numerically?, Phys. Rev. D61, 104015, (2000).
A. Vecchio, Deep Surveys of
Massive Black Holes with LISA in "Gravitational Waves: Third Edoardo Amaldi
Conference, Pasadena, California, 12-16 July, 1999", Ed. S. Meshkov, American
Institute of Physics, Melville NY,403-404, (2000).
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