论文信息 - Efficient filter for detecting gravitational wave bursts in interferometric detectors

Efficient filter for detecting gravitational wave bursts in interferometric detectors

Typical sources of gravitational wave bursts are supernovae, for which no accurate models exist. This calls for search methods with high efficiency and robustness to be used in the data analysis of foreseen interferometric detectors. A set of such filters is designed to detect gravitational wave burst signals. We first present filters based on the linear fit of whitened data to short straight lines in a given time window and combine them in a nonlinear filter named ALF. We study the performances and efficiencies of these filters, with the help of a catalogue of simulated supernova signals. The ALF filter is the best performing and most efficient of all filters. Its performance reaches about 80% of the optimal filter performance designed for the same signals. Such a filter could be implemented as an online trigger (dedicated to detect bursts of unknown wave form) in interferometric detectors of gravitational waves.

[1] S. Mohanty. A robust test for detecting non-stationarity , 2001 .

[2] W. Anderson,et al. Excess power statistic for detection of burst sources of gravitational radiation , 2000, gr-qc/0008066.

[3] L. Conti,et al. Initial operation of the International Gravitational Event Collaboration , 2000, astro-ph/0003106.

[4] N. Arnaud,et al. ABOUT THE DETECTION OF GRAVITATIONAL WAVE BURSTS , 2000, gr-qc/0001062.

[5] W. Anderson,et al. A power filter for the detection of burst sources of gravitational radiation in interferometric detectors , 2000, gr-qc/0001044.

[6] T. Damour,et al. Transition from inspiral to plunge in binary black hole coalescences , 2000, gr-qc/0001013.

[7] S. Mohanty. Robust test for detecting nonstationarity in data from gravitational wave detectors , 1999, gr-qc/9910027.

[8] N. Arnaud,et al. Triggers for the Detection of Gravitational Wave Bursts , 1999, gr-qc/9903035.

[9] E. Cuoco,et al. Adaptive Identification of VIRGO-like Noise Spectrum , 1997, gr-qc/9709041.

[10] B. Caron,et al. The Virgo interferometer for gravitational wave detection , 1997 .

[11] A. Araya,et al. Status of TAMA , 1996 .

[12] Andreas Tünnermann,et al. GEO 600. A 600 m Laser Interferometric Gravitational Wave Antenna , 1994 .

[13] B. Schutz. Data Processing, analysis, and storage for interferometric antennas , 1991 .

[14] John Bingham,et al. Data Processing , 1989, Macmillan Professional Masters.