Your search keyword '"Michele Vallisneri"' showing total 2 results

1. GRAVITATIONAL-WAVE DATA ANALYSIS FROM EARTH TO SPACE: COMPUTATIONAL AND THEORETICAL CHALLENGES

Author

Michele Vallisneri

Subjects

Physics, Supermassive black hole, Theoretical physics, Neutron star, Gravitational wave, Astronomical interferometer, Picometre, Astronomy, Heliocentric orbit, LIGO, Galaxy

Abstract

The Laser Interferometer Space Antenna (LISA) is a joint NASA-ESA deepspace mission consisting of three drag-free spacecraft, separated by 5 x 10 km and following an Earth-trailing solar orbit; LISA will use picometer interferometry to measure the modulations in the inter-spacecraft distances induced by gravitational waves (GWs) of frequency between 10~ and 1 Hz. LISA will seek to detect GWs from binary systems of compact stellar objects in our galaxy, from the inspiral and merger of binaries of massive and supermassive black holes, and from the capture of compact stellar objects into the supermassive black holes at the center of galaxies; it will also set new constraints on background GWs from the early universe, and naturally (but perhaps most interestingly) it will be sensitive to GWs from previously unknown sources within its frequency band. LISA is expected to start collecting data around 2013 (two years after its launch); thus, its deployment will trail by at least ten years the beginning of science operations for ground-based GW interferometers such as LIGO, GEO, Virgo, and TAMA. At the time of writing, these experiments have begun generating result papers with upper limits on the distribution of sources and GW events; more importantly, they can rely on highly developed technical literature and individual expertise on the characterization and operation of detectors, the handling and analysis of data, and the astrophysics and waveform modeling of sources. It follows that the theoretical activity on LISA is likely to be modeled, at least initially, on the tools and techniques developed for the ground-based detectors (henceforth, GBDs). LISA and GBDs have remarkable similarities, but crucial differences. They look at the same (or similar) sources from different windows in the frequency spectrum (10"-l Hz for LISA, 10-10 Hz for GBDs): consequently, the LISA data set will consist of ~ 10 samples/year, while the GBDs are now collecting a rather more daunting ~ 10 samples/year. Thus, the search for continuous, quasimonochromatic sources of unknown position (e.g., galactic binaries for LISA, and spinning, asymmetric neutron stars for GBDs), will be much less computationally taxing for LISA than it is for GBDs. This asymmetry is partially offset for chirping sources such as inspiraling binaries, which will transit slowly through the LISA frequency band, while they move rapidly (in hours or minutes) in and out of the

Published

2006

2. THE LIGO GRAVITATIONAL WAVE OBSERVATORIES: RECENT RESULTS AND FUTURE PLANS

Author

Robert Spero, Soumya D. Mohanty, Alessandra Buonanno, N. Zotov, K. Mason, B. Lantz, David Crooks, Sanichiro Yoshida, Graham Woan, E. Rotthoff, Xavier Siemens, M. Malec, M. Rakhmanov, S. Penn, Karsten Kötter, Rana X. Adhikari, Yi Chen, Q. Z. Shu, G. Stapfer, J. Hanson, B. Machenschalk, Guido Mueller, Pamela J. Russell, S. Richman, Oliver Jennrich, J. Betzwieser, H. Overmier, J. H. Romie, B. Sears, Anton B. Ivanov, C. Colacino, M. Schrempel, N. Hindman, D. Farnham, Vicky Kalogera, Carsten Fallnich, J. Mason, T. Regimbau, M. Coles, M. Guenther, Michael D. Smith, R. Amin, K. Bayer, F. J. Raab, R. Gustafson, V. Schmidt, I. Salzman, Patrick Brady, C. Barker-Patton, C. I. Torrie, M. A. Barton, F. Mann, A. Heptonstall, C. Hardham, R. M. S. Schofield, S. Chatterji, Benjamin J. Owen, W. R. Johnston, Alberto Vecchio, K. V. Tokmakov, Seiji Kawamura, Morag M. Casey, Adrian C. Ottewill, Phil Willems, M. Heurs, J. Chapsky, B. J. Winjum, J. Zweizig, Osamu Miyakawa, David H. Reitze, D. Ouimette, Albert Lazzarini, K. Mailand, Christian J. Killow, Peter R. Saulson, V. V. Frolov, R. Taylor, M. Hammond, H. Ding, Krzysztof Belczynski, R. Mittleman, R. Abbott, Nelson Christensen, A. Hartunian, D. M. Strom, J. Kern, Philippe Grandclément, P. J. Sutton, Haisheng Rong, L. Jones, Robert Bennett, S. Brozek, A. Rizzi, Keisuke Goda, Lindon J. Robison, R. L. Savage, Helena Armandula, E. J. Elliffe, Curt Cutler, P. Kloevekorn, D. Rose, M. C. Araya, B. F. Schutz, T. Summerscales, D. Chin, M. M. Fejer, Stanislav Babak, Walid A. Majid, I. Leonor, S. Wen, P. Ehrens, S. Traeger, Peter Fritschel, A. L. Stuver, I. Yakushin, C. Gray, Duncan A. Brown, G. Billingsley, A. Chandler, D. B. Tanner, J. G. Rollins, Kevin M. Ryan, F. Asiri, S. E. Whitcomb, S. Nagano, Timothy Evans, D. Redding, Shinji Miyoki, M. J. Lubinski, A. M. Gretarsson, Chonghoon Kim, T. Delker, D. Sigg, Brent Ware, S. W. Ballmer, C. Aulbert, S. J. Berukoff, G. Traylor, Thomas Corbitt, J. Castiglione, G. Moreno, Akiteru Takamori, Walter Winkler, P. Charlton, A. Gillespie, Harald Lück, J. Logan, R. K. Nayak, A. Wilson, C. Messenger, Vladimir B. Braginsky, K. Riles, R. Rahkola, V. Leonhardt, T. Etzel, Rainer Weiss, D. Debra, O. Matherny, Laura Cadonati, D. Jungwirth, P. Hoang, P. R. Williams, R. W. P. Drever, I. A. Bilenko, Ian Taylor, Robert J. McCarthy, Linqing Wen, David J. Ottaway, Sheila Rowan, B. Barr, J. Worden, Teviet Creighton, Herbert Walther, M. Hrynevych, K. Kawabe, Joseph D. Romano, Yousuke Itoh, W. W. Johnson, C. King, R. Riesen, Roland Schilling, Kasem Mossavi, F. Nocera, Martin Hewitson, B. Bochner, Alicia M. Sintes, Massimo Tinto, H. Tariq, D. Webber, V. Quetschke, Bangalore Suryanarayana Sathyaprakash, E. Black, Gianpietro Cagnoli, Gregory M. Harry, M. Lei, J. R. Smith, R. Bork, J. E. Brau, C. A. Cantley, T. Nash, T. Olson, A. Sazonov, D. Churches, Benjamin William Allen, A. Khan, S. M. Scott, D. Ugolini, Karsten Danzmann, M. C. Sumner, Virginio Sannibale, David E. McClelland, Kenneth A. Strain, M. Lormand, Erika D'Ambrosio, J. Myers, C. Ebeling, J. A. Giaime, G. Mendell, U. Weiland, E. J. Daw, M. Fine, T. T. Lyons, S. Wise, S. Grunewald, C. Parameswariah, N. Hepler, B. Mours, J. Langdale, G. P. Newton, M. Fyffe, Kip S. Thorne, Suvadeep Bose, Richard Ingley, A. J. Weinstein, D. H. Shoemaker, Gabriela Gonzalez, M. Landry, Kenneth G. Libbrecht, D. B. Kozak, M. Hennessy, C. Vorvick, B. O'Reilly, R.L. Coldwell, A. Weidner, V. P. Mitrofanov, L. Bogue, M. R. Smith, P. Schwinberg, A. Grant, S. Liu, Michael E Zucker, L. Zhang, G. H. Sanders, R. Lawrence, W. G. Anderson, Jordan Camp, A. S. Sengupta, Peter Shawhan, M. Tibbits, B. P. Abbott, S. Vass, Peter Aufmuth, W. Kells, D. Busby, R. Davies, William E. Butler, Albrecht Rüdiger, V. Chickarmane, S. Meshkov, R. Beausoleil, Martin P McHugh, M. H. P. M. van Putten, S. Tilav, E. Gustafson, H. Naundorf, M. R. Pratt, Matthew Evans, L. Cardenas, E. Maros, S. Klimenko, Marco Aurelio Diaz, B. Bhawal, V. Parameswariah, C. Torres, N. A. Robertson, A. Bullington, Kevin M. Carter, S. B. Anderson, M. W. Regehr, A. Marin, M. Pedraza, Badri Krishnan, P. Csatorday, Maria Alessandra Papa, M. V. Plissi, Antony C. Searle, Kent Blackburn, Hartmut Grote, B. F. Whiting, Joseph M. Kovalik, M. Barnes, Julien Sylvestre, P. McNamara, L. Wallace, R. Frey, H. Yamamoto, P. J. King, D. Grimmett, Philip Nutzman, A. G. Wiseman, P. E. Lindquist, D. C. Coyne, S. Dhurandar, W. O. Hamilton, D. Barker, Kenneth D. Skeldon, S. Killbourn, S. Roddy, James Whelan, Lee Samuel Finn, Éanna É. Flanagan, Guenakh Mitselmakher, A. Ageev, L. Sievers, C. A. Shapiro, B. Bland-Weaver, Soma Mukherjee, Scott Koranda, L. Matone, J. H. Hough, A. Sibley, Douglas R. Cook, S. Seel, M. Ito, Roy Williams, K. S. Ganezer, K. Watts, Stefan Goßler, K. T. Reilly, Kevin C. Schlaufman, Herbert Welling, Nergis Mavalvala, B. C. Barish, J. Heefner, W. Hua, Michele Vallisneri, Ik Siong Heng, S. Márka, R. J. Dupuis, K. Reithmaier, Andreas Freise, Matthew Pitkin, R. DeSalvo, R. Wooley, Jolien D. E. Creighton, I. Zawischa, E. Katsavounidis, R. L. Byer, H. Radkins, S. P. Vyachanin, W. Tyler, R. Balasubramanian, Jeffrey A. Edlund, R. Burgess, B. J. Cusack, S. R. Rao, D. I. Robertson, Peter H. Sneddon, M. Mageswaran, H. Ward, M. MacInnis, Y. Hefetz, Gerhard Heinzel, Benno Willke, and The LIGO Scientific Collaboration

Subjects

Physics, Gravitational-wave observatory, Einstein Telescope, Gravitational wave, Astrophysics::High Energy Astrophysical Phenomena, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy, Astrophysics, Gravitational-wave astronomy, LIGO, General Relativity and Quantum Cosmology, Neutron star, Pulsar, QC

Abstract

The LIGO interferometers are operating as gravitational wave observatories, with a noise level near an order of magnitude of the goal and the first scientific data recently taken. This data has been analyzed for four different categories of gravitational wave sources; millisecond bursts, inspiralling binary neutron stars, periodic waves from a known pulsar, and stochastic background. Research and development is also underway for the next generation LIGO detector, Advanced LIGO.

Published

2006