Time-frequency analysis of gravitational wave data

Data from gravitational wave detectors are recorded as time series that include contributions from myriad noise sources in addition to any gravitational wave signals. When regularly sampled data are available, such as for ground based and future space based interferometers, analyses are typically performed in the frequency domain, where stationary (time invariant) noise processes can be modeled very efficiently. In reality, detector noise is not stationary due to a combination of short duration noise transients and longer duration drifts in the power spectrum. This non-stationarity produces correlations across samples at different frequencies, obviating the main advantage of a frequency domain analysis. Here an alternative time-frequency approach to gravitational wave data analysis is proposed that uses discrete, orthogonal wavelet wavepackets. The time domain data is mapped onto a uniform grid of time-frequency pixels. For locally stationary noise - that is, noise with an adiabatically varying spectrum - the time-frequency pixels are uncorrelated, which greatly simplifies the calculation of quantities such as the likelihood. Moreover, the gravitational wave signals from binary systems can be compactly represented as a collection of lines in time-frequency space, resulting in a computational cost for computing waveforms and likelihoods that scales as the square root of the number of time samples, as opposed to the linear scaling for time or frequency based analyses. Key to this approach is having fast methods for computing binary signals directly in the wavelet domain. Multiple fast transform methods are developed in detail.

[1]  Anne E. McMills Tech , 2021, The Assistant Lighting Designer's Toolkit.

[2]  N. Cornish,et al.  Black hole hunting with LISA , 2020, Physical Review D.

[3]  T. Littenberg,et al.  Global analysis of the gravitational wave signal from Galactic binaries , 2020, Physical Review D.

[4]  Santiago de Compostela,et al.  Dynamic normalization for compact binary coalescence searches in non-stationary noise , 2020, Classical and Quantum Gravity.

[5]  M. Colleoni,et al.  Multimode frequency-domain model for the gravitational wave signal from nonprecessing black-hole binaries , 2020, 2001.10914.

[6]  B. A. Boom,et al.  A guide to LIGO–Virgo detector noise and extraction of transient gravitational-wave signals , 2019, Classical and Quantum Gravity.

[7]  Gregorio Carullo,et al.  Erratum: Observational black hole spectroscopy: A time-domain multimode analysis of GW150914 [Phys. Rev. D 99 , 123029 (2019)] , 2019, Physical Review D.

[8]  T. Canton,et al.  Gravitational-wave parameter estimation with gaps in LISA: A Bayesian data augmentation method , 2019, Physical Review D.

[9]  S. Teukolsky,et al.  Testing the No-Hair Theorem with GW150914. , 2019, Physical review letters.

[10]  Gregorio Carullo,et al.  Observational black hole spectroscopy: A time-domain multimode analysis of GW150914 , 2018, Physical Review D.

[11]  R. Sarpong,et al.  Bio-inspired synthesis of xishacorenes A, B, and C, and a new congener from fuscol† †Electronic supplementary information (ESI) available. See DOI: 10.1039/c9sc02572c , 2019, Chemical science.

[12]  Jonah Kanner,et al.  Mitigation of the instrumental noise transient in gravitational-wave data surrounding GW170817 , 2018, Physical Review D.

[13]  T. Robson,et al.  Towards a Fourier domain waveform for non-spinning binaries with arbitrary eccentricity , 2018, Classical and Quantum Gravity.

[14]  T. Littenberg,et al.  Bayesian reconstruction of gravitational wave bursts using chirplets , 2017, Physical Review D.

[15]  B. A. Boom,et al.  GW170817: Observation of Gravitational Waves from a Binary Neutron Star Inspiral. , 2017, Physical review letters.

[16]  K. Chatziioannou,et al.  Constructing gravitational waves from generic spin-precessing compact binary inspirals , 2017, 1703.03967.

[17]  Cody Messick,et al.  Analysis framework for the prompt discovery of compact binary mergers in gravitational-wave data , 2016, 1604.04324.

[18]  David Blair,et al.  Characterization of transient noise in Advanced LIGO relevant to gravitational wave signal GW150914 , 2016, Classical and quantum gravity.

[19]  G. Mitselmakher,et al.  Method for detection and reconstruction of gravitational wave transients with networks of advanced detectors , 2015, 1511.05999.

[20]  Michael Purrer,et al.  Frequency-domain gravitational waves from nonprecessing black-hole binaries. II. A phenomenological model for the advanced detector era , 2015, 1508.07253.

[21]  N. Christensen,et al.  Bayesian semiparametric power spectral density estimation with applications in gravitational wave data analysis , 2015, 1506.00185.

[22]  M. S. Shahriar,et al.  Characterization of the LIGO detectors during their sixth science run , 2014, 1410.7764.

[23]  Neil J. Cornish,et al.  Bayesian inference for spectral estimation of gravitational wave detector noise , 2014, 1410.3852.

[24]  Neil J. Cornish,et al.  Bayeswave: Bayesian inference for gravitational wave bursts and instrument glitches , 2014, 1410.3835.

[25]  Frank Ohme,et al.  Twist and shout: A simple model of complete precessing black-hole-binary gravitational waveforms , 2013, 1308.3271.

[26]  N. Cornish,et al.  Detecting a Stochastic Gravitational Wave Background in the presence of a Galactic Foreground and Instrument Noise , 2013, 1307.4116.

[27]  Marco Drago,et al.  Regression of environmental noise in LIGO data , 2013, 1503.07476.

[28]  Pantelimon Stanica,et al.  The inverse of banded matrices , 2013, J. Comput. Appl. Math..

[29]  Michael Vogt,et al.  Nonparametric regression for locally stationary time series , 2012, 1302.4198.

[30]  V. Necula,et al.  Transient analysis with fast Wilson-Daubechies time-frequency transform , 2012 .

[31]  K. S. Thorne,et al.  The characterization of Virgo data and its impact on gravitational-wave searches , 2012, 1203.5613.

[32]  Bruce Allen,et al.  FINDCHIRP: an algorithm for detection of gravitational waves from inspiraling compact binaries , 2005, gr-qc/0509116.

[33]  W. Marsden I and J , 2012 .

[34]  Calyampudi Radhakrishna Rao,et al.  Time series analysis : methods and applications , 2012 .

[35]  M Hannam,et al.  Inspiral-merger-ringdown waveforms for black-hole binaries with nonprecessing spins. , 2009, Physical review letters.

[36]  P. Ajith,et al.  Matching post-Newtonian and numerical relativity waveforms: Systematic errors and a new phenomenological model for nonprecessing black hole binaries , 2010, 1005.3306.

[37]  Yi Pan,et al.  Comparison of post-Newtonian templates for compact binary inspiral signals in gravitational-wave detectors , 2009, 0907.0700.

[38]  Y. Levin,et al.  On measuring the gravitational-wave background using Pulsar Timing Arrays , 2008, 0809.0791.

[39]  P. Ajith,et al.  Template bank for gravitational waveforms from coalescing binary black holes: Nonspinning binaries , 2008 .

[40]  T. Littenberg,et al.  Tests of Bayesian model selection techniques for gravitational wave astronomy , 2007, 0704.1808.

[41]  J. Macías-Pérez,et al.  A wavelet analysis of CMB time-ordered data applied to Archeops , 2005, astro-ph/0511200.

[42]  Tx,et al.  Constraint Likelihood analysis for a network of gravitational wave detectors , 2005, gr-qc/0508068.

[43]  B. Allen χ2 time-frequency discriminator for gravitational wave detection , 2004, gr-qc/0405045.

[44]  E. Katsavounidis,et al.  Multiresolution techniques for the detection of gravitational-wave bursts , 2004, gr-qc/0412119.

[45]  E. Cuoco,et al.  Whitening of non-stationary noise from gravitational wave detectors , 2004 .

[46]  J. Raz,et al.  Automatic Statistical Analysis of Bivariate Nonstationary Time Series , 2001 .

[47]  G. Losurdo,et al.  Noise parametric identification and whitening for LIGO 40-m interferometer data , 2001, gr-qc/0104071.

[48]  G. Calamai,et al.  On line power spectra identification and whitening for the noise in interferometric gravitational wave detectors , 2000, gr-qc/0011041.

[49]  G. Nason,et al.  Wavelet processes and adaptive estimation of the evolutionary wavelet spectrum , 2000 .

[50]  R. V. Sachs,et al.  Wavelets in time-series analysis , 1999, Philosophical Transactions of the Royal Society of London. Series A: Mathematical, Physical and Engineering Sciences.

[51]  S. Mallat,et al.  Adaptive covariance estimation of locally stationary processes , 1998 .

[52]  C. Cutler Angular resolution of the LISA gravitational wave detector , 1997, gr-qc/9703068.

[53]  Kevin Amaratunga,et al.  A Discrete Wavelet Transform without edge effects using wavelet extrapolation , 1997 .

[54]  R. Dahlhaus Fitting time series models to nonstationary processes , 1997 .

[55]  N. Kasdin Discrete simulation of colored noise and stochastic processes and 1/fα power law noise generation , 1995, Proc. IEEE.

[56]  Finn,et al.  Detection, measurement, and gravitational radiation. , 1992, Physical review. D, Particles and fields.

[57]  R. Webbink,et al.  Gravitational radiation from the Galaxy , 1990 .

[58]  M. Priestley Evolutionary Spectra and Non‐Stationary Processes , 1965 .

[59]  D. Gabor,et al.  Theory of communication. Part 1: The analysis of information , 1946 .

[60]  W. K. Brasher,et al.  Journal of the Institution of Electrical Engineers , 1941, Nature.