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Gravitational wave astrophysics, data analysis and multimessenger astronomy 被引量:5

Gravitational wave astrophysics, data analysis and multimessenger astronomy
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摘要 This paper reviews gravitational wave sources and their detection. One of the most exciting potential sources of gravitational waves are coalescing binary black hole systems. They can occur on all mass scales and be formed in numerous ways, many of which are not understood. They are generally invisible in electromagnetic waves, and they provide opportunities for deep investigation of Einstein's general theory of relativity. Sect. 1 of this paper considers ways that binary black holes can be created in the universe, and includes the prediction that binary black hole coalescence events are likely to be the first gravitational wave sources to be detected. The next parts of this paper address the detection of chirp waveforms from coalescence events in noisy data.Such analysis is computationally intensive. Sect. 2 reviews a new and powerful method of signal detection based on the GPUimplemented summed parallel infinite impulse response filters. Such filters are intrinsically real time alorithms, that can be used to rapidly detect and localise signals. Sect. 3 of the paper reviews the use of GPU processors for rapid searching for gravitational wave bursts that can arise from black hole births and coalescences. In sect. 4 the use of GPU processors to enable fast efficient statistical significance testing of gravitational wave event candidates is reviewed. Sect. 5 of this paper addresses the method of multimessenger astronomy where the discovery of electromagnetic counterparts of gravitational wave events can be used to identify sources, understand their nature and obtain much greater science outcomes from each identified event. This paper reviews gravitational wave sources and their detection. One of the most exciting potential sources of gravitational waves are coalescing binary black hole systems. They can occur on all mass scales and be formed in numerous ways, many of which are not understood. They are generally invisible in electromagnetic waves, and they provide opportunities for deep investigation of Einstein's general theory of relativity. Sect. 1 of this paper considers ways that binary black holes can be created in the universe, and includes the prediction that binary black hole coalescence events are likely to be the first gravitational wave sources to be detected. The next parts of this paper address the detection of chirp waveforms from coalescence events in noisy data. Such analysis is computationally intensive. Sect. 2 reviews a new and powerful method of signal detection based on the GPU- implemented summed parallel infinite impulse response filters. Such filters are intrinsically real time alorithms, that can be used to rapidly detect and localise signals. Sect. 3 of the paper reviews the use of GPU processors for rapid searching for gravitational wave bursts that can arise from black hole births and coalescences. In sect. 4 the use of GPU processors to enable fast efficient statistical significance testing of gravitational wave event candidates is reviewed. Sect. 5 of this paper addresses the method of multimessenger astronomy where the discovery of electromagnetic counterparts of gravitational wave events can be used to identify sources, understand their nature and obtain much greater science outcomes from each identified event.
出处 《Science China(Physics,Mechanics & Astronomy)》 SCIE EI CAS CSCD 2015年第12期44-64,共21页 中国科学:物理学、力学、天文学(英文版)
基金 supported by the NRF from the Korean government(Grant No.2006-00093852) the National Natural Science Foundation of China(Grant Nos.61440057,61272087,61363019,61073008 and 11303009) Beijing Natural Science Foundation(Grant Nos.4082016 and 4122039) the Sci-Tech Interdisciplinary Innovation and Cooperation Team Program of the Chinese Academy of Sciences the Specialized Research Fund for State Key Laboratories,National Science Foundation(Grant Nos.PHY-1206108 and PHY-1506497) the Perseus Computing Cluster at the Inter University Centre for Astronomy and Astrophysics(IUCAA),Pune,India the hospitality and financial support provided by the Kavli Institute for Theoretical Physics in Beijing
关键词 gravitational waves data analysis multimessenger 引力波 天文学 天体物理学 数据分析 无限脉冲响应滤波器 信号检测 数据合并 广义相对论
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  • 1Kim C, Perera B B P, McLaughlin M, et al. Implications of PSR J0737-3039B for the Galactic NS-NS binary merger rate. Mon Not R Astron Soc, 2015, 448(1): 928-938.
  • 2Abadie J, Abbott B P, Abbott R, et al. Predictions for the rates of compact binary coalescences observable by ground-based gravitationalwave detectors. Class Quantum Grav, 2010, 27(17): 173001.
  • 3Press W H, Teukolsky S A. Formation of close binaries by 2-body tidal capture. Astrophys J, 1977, 213(1): 183-192.
  • 4Lee H M, Ostriker J P. Cross-sections for tidal capture binary formation and stellar merger. Astrophys J, 1986, 310(1): 176-188.
  • 5Peters P C, Mathews J. Gravitational radiation from point masses in a Keplerian orbit. Phys Rev, 1963, 131(1): 435.
  • 6Goodman J, Hut P. Binary single-star scattering. 5. steady state binary distribution in a homogeneous static background of single stars. Astrophys J, 1993, 403(1): 271.
  • 7Farrell S A, Webb N A, Natalie A, et al. An intermediate-mass black hole of over 500 solar masses in the galaxy ESO 243-49. Nature,2009, 460(7251): 73-75.
  • 8Lee H M. Evolution of galactic nuclei with 10-m (circle dot), blackholes. Mon Not R Astron Soc, 1995, 272(3): 605-617.
  • 9Quinlan G D, Shapiro S L. Dynamical evolution of dense clusters of compact stars. Astrophys J, 1989, 343(2): 725-749.
  • 10Bahcall J N, Wolf R A. Star distribution around a massive black-hole in a globular cluster. Astrophys J, 1976, 209(1): 214-232.

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