Search for gravitational waves from compact binary coalescence in LIGO and Virgo data from S5 and VSR1

Abadie, J.; Abbott, B. P.; Abbott, R.; Abernathy, M. R.; Accadia, T.; Acernese, F.; Adams, C.; Adhikari, R. X.; Ajith, P.; Allen, B.; Allen, G.; Ceron, E. Amador; Amin, R. S.; Anderson, S. B.; Anderson, W. G.; Antonucci, F.; Arain, M. A.; Araya, M. C.; Aronsson, M.; Arun, K. G.; Aso, Y.; Aston, S. M.; Astone, P.; Atkinson, D.; Aufmuth, P.; Aulbert, C.; Babak, S.; Baker, P. T.; Ballardin, G.; Ballinger, Thomas J.; Ballmer, S. W.; Barker, D.; Barnum, S.; Barone, F.; Barr, B.; Barriga, P.; Barsotti, L.; Barsuglia, M.; Barton, M. A.; Bartos, I.; Bassiri, R.; Bastarrika, M.; Bauchrowitz, J.; Bauer, T. S.; Behnke, B.; Beker, M. G.; Belĺetoile, A.; Benacquista, M.; Bertolini, A.; Betzwieser, J.; Beveridge, N.; Beyersdorf, P. T.; Bigotta, S.; Bilenko, I. A.; Billingsley, G.; Birch, J.; Birindelli, S.; Biswas, R.; Bitossi, M.; Bizouard, M. A.; Black, E.; Blackburn, J. K.; Blackburn, L.; Blair, David; Bland, B.; Blom, M.; Boccara, Claude; Böck, O.; Bodiya, T. P.; Bondarescu, Ruxandra; Bondu, F.; Bonelli, L.; Bonnand, R.; Bork, R.; Born, M.; Bose, S.; Bosi, L.; Bouhou, B.; Boyle, Michael; Braccini, S.; Bradaschia, C.; Brady, P. R.; Braginsky, V. B.; Brau, J.; Breyer, J.; Bridges, D. O.; Brillet, A.; Brinkmann, M.; Brisson, V.; Britzger, M.; Brooks, A. F.; Brown, D. A.; Budzyński, R.; Bulik, T.; Bulten, H.; Buonanno, A.; Burguet–Castell, J.; Burmeister, O.; Buskulic, D.; Lesvigne-Buy, Christelle; Byer, R. L.; Cadonati, L.; Cagnoli, G.; Cain, J.; Calloni, E.; Camp, J. B.; Campagna, E.; Campsie, P.; Cannizzo, J. K.; Cannon, K. C.; Canuel, B.; Cao, Junwei; Capano, C. D.; Carbognani, F.; Caudill, S.; Cavaglià, M.; Cavalier, F.; Cavalieri, R.; Cella, G.; Cepeda, C.; Cesarini, E.; Chalermsongsak, T.; Chalkley, E.; Charlton, P.; Chassande–Mottin, E.; Chelkowski, S.; Chen, Y.; Chincarini, A.; Christensen, N.; Chua, S.; Chung, C. T.Y.; Clark, D.; Clark, J. A.; Clayton, J. H.; Cleva, F.; Coccia, E.; Colacino, C. N.; Colas, J.; Colla, A.; Colombini, M.; Conte, R.; Cook, D.; Corbitt, T. R.; Cornish, N.; Corsi, A.; Costa, C. A.; Coulon, J.‐P.; Coward, D. M.; Coyne, D. C.; Creighton, J. D. E.; Creighton, T. D.; Cruise, A. M.; Culter, R. M.; Cumming, A.; Cunningham, L.; Cuoco, E.; Dahl, K.; Danilishin, S. L.; Dannenberg, R.; D’Antonio, S.; Danzmann, K.; Das, K.; Dattilo, V.; Daudert, B.; Davier, M.; Davies, G. S.; Davis, A.; Daw, E. J.; Day, R.; Dayanga, T.; De, Rounds; DeBra, D.; Degallaix, J.; Del, M. Prete; Dergachev, V.; DeRosa, R.; DeSalvo, R.; Devanka, P.; Dhurandhar, S.; Di, L. Fiore; Di, A. Lieto; Di, I. Palma; Emilio, M. Di Paolo; Di, A. Virgilio; Díaz, M. C.; Dietz, A.; Donovan, F.; Dooley, K. L.; Doomes, E. E.; Dorsher, S.; Douglas, Ewan S.; Drago, M.; Drever, R. W. P.; Driggers, J. C.; Dueck, J.; Dumas, J. C.; Eberle, T.; Edgar, M.; Edwards, M. C.; Effler, A.; Ehrens, P.; Ely, Gabriela Zenatti; Engel, R.; Etzel, T.; Evans, M.; Evans, T. M.; Fafone, V.; Fairhurst, S.; Fan, Y.; Farr, B.; Fazi, D.; Fehrmann, H.; Feldbaum, D.; Ferrante, I.; Fidecaro, F.; Finn, L. S.; Fiori, I.; Flaminio, R.; Flanigan, Meghan E.; Flasch, Kurt; Foley, S.; Forrest, C.; Forsi, E.; Fotopoulos, N.; Fournier, J.-D.; Franc, J.; Frasca, S.; Frasconi, F.; Frede, M.; Frei, M.; Frei, Z.; Freise, A.; Frey, R.; Fricke, T. T.; Friedrich, Daniel; Fritschel, P.; Фролов, В. В.; Fulda, P.; Fyffe, M.; Galimberti, M.; Gammaitoni, L.; Garofoli, J.; Garufi, F.; Gemme, G.; Genin, É.; Gennai, A.; Ghosh, S.; Giaime, J. A.; Giampanis, S.; Giardina, K. D.; Giazotto, A.; Gill, C.; Goetz, E.; Goggin, L. M.; González, Gabriela; Goler, S.; Gouaty, R.; Graef, C.; Granata, M.; Grant, A.; Gras, S.; Gray, C.; Greenhalgh, R. J. S.; Gretarsson, A. M.; Greverie, C.; Grosso, R.; Grote, H.; Grünewald, S.; Guidi, G. M.; Gustafson, E. K.; Gustafson, R.; Hage, B.; Hall, Peter; Hallam, J. M.; Hammer, D. A.; Hammond, G.; Hanks, J.; Hanna, C.; Hanson, J.; Harms, J.; Harry, G. M.; Harry, I. W.; Harstad, E. D.; Haughian, K.; Hayama, K.; Hayau, J.-F.; Hayler, T.; Heefner, J.; Heitmann, H.; Hello, P.; Heng, I. S.; Heptonstall, A. W.; Hewitson, M.; Hild, S.; Hirose, E.; Hoak, D.; Hodge, K. A.; Holt, K.; Hosken, D. J.; Hough, J.; Howell, E. J.; Hoyland, D.; Huet, D.; Hughey, B.; Husa, S.; Huttner, S. H.; Huynh─Dinh, T.; Ingram,; Inta, R.; Isogai, T.; Ivanov, A.; Jaranowski, P.; Johnson, W. W.; Jones, D. I.; Jones, Gareth; Jones, R.; Li, Ju; Kalmus, P.; Kalogera, V.; Kandhasamy, S.; Kanner, J. B.; Katsavounidis, E.; Kawabe, K.; Kawamura, Seiji; Kawazoe, F.; Kells, W.; Keppel, D. G.; Khalaidovski, A.; Khalili, F. Y.; Khazanov, E. A.; Kim, H.; King, P. J.; Kinzel, D. L.; Kissel, J. S.; Klimenko, S.; Kondrashov, V.; Kopparapu, R.; Koranda, S.; Kowalska, I.; Kozak, D. 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C.; Mendell, G.; Menéndez, D. F.; Mercer, R. A.; Merill, L.; Meshkov, S.; Messenger, C.; Meyer,; Miao, H.; Michel, C.; Milano, L.; Miller, John M.; Minenkov, Y.; Mino, Yasushi; Mitra, S.; Mitrofanov, V. P.; Mitselmakher, G.; Mittleman, R.; Moe, B.; Mohan, M.; Mohanty, S. D.; Mohapatra, S. R. P.; Moraru, D.; Moreau, Julien; Moreno, G.; Morgado, N.; Morgia, A.; Mors, K.; Mosca, S.; Moscatelli, V.; Mossavi, K.; Mours, B.; Mow–Lowry, C. M.; Mueller, G.; Mukherjee, Soma; Mullavey, A.; Ller-Ebhardt, Hm.; Münch, J.; Murray, P. G.; Nash, T.; Nawrodt, R.; Nelson, J.; Neri, I.; Newton, G.; Nishida, E.; Nishizawa, A.; Nocera, F.; Nolting, D.; Ochsner, E.; O’Dell, J.; Ogin, G. H.; Oldenburg, R. G.; O’Reilly, B.; O’Shaughnessy, R.; Osthelder, C.; Ottaway, D. J.; Ottens, R. S.; Overmier, H.; Owen, B. J.; Page, Amanda J.; Pagliaroli, G.; Palladino, L.; Palomba, C.; Pan, Y.; Pankow, C.; Paoletti, F.; Papa, M. A.; Pardi, S.; Pareja, M.; Parisi, M.; Pasqualetti, A.; Passaquieti, R.; Passuello, D.; Patel, P.; Pathak, D.; Pedraza, M.; Pekowsky, L.; Penn, S.; Peralta, C.; Perreca, A.; Persichetti, G.; Pichot, M.; Pickenpack, M.; Piergiovanni, F.; Piȩtka, M.; Pinard, L.; Pinto, I. M.; Pitkin, M.; Pletsch, H. J.; Plissi, M. V.; Poggiani, R.; Postiglione, F.; Prato, Mirko; Predoi, V.; Price, L. R.; Prijatelj, M.; Principe, M.; Prix, R.; Prodi, G. A.; Prokhorov, L.; Puncken, O.; Punturo, M.; Puppo, P.; Quetschke, V.; Raab, F. J.; Rabeling, D. S.; Radke, Thomas; Radkins, H.; Raffai, P.; Rakhmanov, M.; Rankins, B.; Rapagnani, P.; Raymond, V.; Re, V.; Reed, C. M.; Reed, T.; Regimbau, T.; Reid, S.; Reitze, D. H.; Ricci, F.; Riesen, Rolf; Riles, K.; Roberts, P.; Robertson, N. A.; Robinet, F.; Robinson, C.; Robinson, E. L.; Rocchi, A.; Roddy, S.; Röver, Christian; Rolland, L.; Rollins, J. G.; Romano, J. D.; Romano, R.; Romie, J. 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J.; Swinkels, B. L.; Talukder, D.; Tanner, D. B.; Tarabrin, S. P.; Taylor, J. R.; Taylor, Robert W.; Thomas, P.; Thorne, K. S.; Thorne, K. S.; Thrane, E.; Ring, A.; Titsler, C.; Tokmakov, K. V.; Toncelli, A.; Tonelli, M.; Torre, O.; Torres, C.; Torrie, C. I.; Tournefier, E.; Travasso, F.; Traylor, G.; Trias, M.; Trummer, J.; Tseng, K.; Turner, L.; Ugolini, D.; Urbánek, Karel; Vahlbruch, H.; Vaishnav, B.; Vajente, G.; Vallisneri, Michele; Van, Jfj. Den Brand; Van, Den Broeck C.; Van, S. Der Putten; Van, Aa. Der Sluys Mv.; Van, Veggel; Vass, S.; Vaulin, R.; Vavoulidis, M.; Vecchio, A.; Vedovato, G.; Veitch, J.; Veitch, P. J.; Veltkamp, C.; Verkindt, D.; Vetrano, F.; Viceré, A.; Villar, A.; Vinetj, Y.; Vocca, H.; Vorvick, C.; Vyachanin, S. P.; Waldman, S. J.; Wallace, L.; Wanner, A.; Ward, R. L.; Was, M.; Wei, Peng; Weinert, M.; Weinstein, A. J.; Weiss, R.; Wen, L.; Wen, S.; Weßels, P.; West, M.; Westphal, T.; Wette, K.; Whelan, J. T.; Whitcomb, S. E.; White, David; Whiting, B. F.; Wilkinson, C.; Willems, P. A.; Williams, L.; Willke, B.; Winkelmann, L.; Winkler, W.; Wipf, C. C.; Wiseman, A. G.; Woan, G.; Wooley, R.; Worden, J.; Yakushin, I.; Yamamoto, H.; Yamamoto, K.; Yeaton-Massey, D.; Yoshida, S.; Yu, P.; Yvert, M.; Zanolin, M.; Zhang, L.; Zhang, Zhen; Zhao, C.; Zotov, N.; Zucker, M. E.; Zweizig, J.

doi:10.1103/physrevd.82.102001

Cited by 119 publications

(78 citation statements)

References 29 publications

(27 reference statements)

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“…An inspiral analysis pipeline typically includes data selection, template bank generation, trigger generation using FINDCHIRP, trigger coincidence tests between multiple detectors, vetoes based on instrumental behavior, coherent combination of the optimal filter output from multiple detectors, and finally manual candidate followups. Pipelines vary between specific analyses and the topology of the analysis pipelines has evolved due to the specific demands of particular observing runs [14][15][16]18,19,[21][22][23][24][25].…”

Section: Discussionmentioning

confidence: 99%

“…The FINDCHIRP algorithm is the implementation of matched filtering used by the LIGO Scientific Collaboration (LSC) and Virgo's offline searches for gravitational waves from low-mass (2M < M ¼ m 1 þ m 2 < 35M ), high-mass (25M < M < 100M ), and primordial black hole (0:2M < M < 2M ) coalescing compact binaries [14][15][16][17][18][19][20][21][22][23][24][25]. FINDCHIRP has also been used to search for supermassive black holes in data from the LISA Mock Data Challenge [26][27][28] and for comparisons with numerical relativity waveforms for both high-mass and low-mass binaries [29].…”

Section: Introductionmentioning

confidence: 99%

“…We refer to Refs. [14][15][16]18,19,[21][22][23][24][25][30][31][32] for descriptions of the pipelines that have used the algorithms described here. This paper is not intended to provide documentation for our implementation of the FINDCHIRP algorithm.…”

Section: Introductionmentioning

confidence: 99%

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FINDCHIRP: An algorithm for detection of gravitational waves from inspiraling compact binaries

et al. 2012

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Matched-filter searches for gravitational waves from coalescing compact binaries by the LIGO Scientific Collaboration use the FINDCHIRP algorithm: an implementation of the optimal filter with innovations to account for unknown signal parameters and to improve performance on detector data that has nonstationary and non-Gaussian artifacts. We provide details on the FINDCHIRP algorithm as used in the search for subsolar mass binaries, binary neutron stars, neutron starblack hole binaries, and binary black holes.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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FINDCHIRP: An algorithm for detection of gravitational waves from inspiraling compact binaries

et al. 2012

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“…These systems generate well understood "chirp" gravitational-wave signals, which have been computed using post-Newtonian approximation [13,14] or numerical relativity simulations [15]. One can then search for the chirp signals using matched template techniques -indeed a number of such searches have been performed using LIGO and Virgo data [16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Accessibility of the gravitational-wave background due to binary coalescences to second and third generation gravitational-wave detectors

2012

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International audienceCompact binary coalescences, such as binary neutron stars or black holes, are among the most promising candidate sources for the current and future terrestrial gravitational-wave detectors. While such sources are best searched using matched template techniques and chirp template banks, integrating chirp signals from binaries over the entire universe also leads to a gravitational-wave background (GWB). In this paper we systematically scan the parameter space for the binary coalescence GWB models, taking into account uncertainties in the star formation rate and in the delay time between the formation and coalescence of the binary, and we compare the computed GWB to the expected sensitivities of the second and third generation gravitational-wave detector networks. We find that second generation detectors are likely to detect the binary coalescence GWB, while the third generation detectors will probe most of the available parameter space. The binary coalescence GWB will, in fact, be a foreground for the third generation detectors, potentially masking the GWB background due to cosmological sources. Accessing the cosmological GWB with third generation detectors will therefore require identification and subtraction of all inspiral signals from all binaries in the detectors’ frequency band

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“…Inspiral signals come from the final stages of a neutron star or black hole binary, as the compact objects merge together [2]. This should produce a distinctive signal, increasing in frequency until the merger.…”

Section: Detection Of Gravitational Wavesmentioning

confidence: 99%

Neutron Star Oscillations From Starquakes

Keer¹

2015

The Thirteenth Marcel Grossmann Meeting

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Glitches are sudden increases in the otherwise extremely regular spin rate of pulsars.One theory proposed to account for these glitches is the starquake model, in which the spinup is caused by a sudden rearrangement of the neutron star crust.Starquakes can be expected to excite some of the oscillation modes of the neutron star.These oscillations are of interest as a source of gravitational waves, and may also modify the pulsar radio emission. In this thesis we develop a toy model of the starquake and calculate which modes of the star are excited.We start by making some order-of-magnitude upper estimates on the energy made available by the starquake and the amplitude of the modes excited, before moving on to a more detailed calculation based on a specific model of the starquake in which all strain is lost instantaneously from the star at the glitch. To find out which modes are excited by the starquake, we construct initial data describing the change in the star at the glitch, and then project this against the basis of normal modes of the star.We first carry out this procedure for a simplified model in which the star has spun down to zero angular velocity before the starquake. We find that the majority of the energy released goes into a mode similar to the fundamental mode of a fluid star.Finally, we describe the extension of this model to the more realistic case where the star is rotating before the glitch. We calculate the change in the normal modes of the star to first order in the rotation; these are no longer orthogonal, but we construct a scheme that still enables us to project our initial data against this set of modes, and discuss some preliminary results of the model.

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Search for gravitational waves from compact binary coalescence in LIGO and Virgo data from S5 and VSR1

Cited by 119 publications

References 29 publications

FINDCHIRP: An algorithm for detection of gravitational waves from inspiraling compact binaries

FINDCHIRP: An algorithm for detection of gravitational waves from inspiraling compact binaries

Accessibility of the gravitational-wave background due to binary coalescences to second and third generation gravitational-wave detectors

Neutron Star Oscillations From Starquakes

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