Detecting highly oscillatory signals by chirplet path pursuit

This paper considers the problem of detecting nonstationary phenomena, and chirps in particular, from very noisy data. Chirps are waveforms of the very general form A ( t ) exp ( ı λ φ ( t ) ) , where λ is a (large) base frequency, the phase φ ( t ) is time-varying and the amplitude A ( t ) is slowl...

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Published in	Applied and computational harmonic analysis Vol. 24; no. 1; pp. 14 - 40
Main Authors	Candès, Emmanuel J., Charlton, Philip R., Helgason, Hannes
Format	Journal Article
Language	English
Published	Elsevier Inc 2008
Subjects	Adaptivity Chirplets Chirps Dynamic programming Graphs Gravitational waves Likelihood ratios Nonparametric testing Shortest path in a graph Signal detection Time–frequency analysis Adaptivity Shortest path in a graph Likelihood ratios Nonparametric testing Gravitational waves Graphs Time–frequency analysis Dynamic programming Chirplets Signal detection Chirps
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Abstract	This paper considers the problem of detecting nonstationary phenomena, and chirps in particular, from very noisy data. Chirps are waveforms of the very general form A ( t ) exp ( ı λ φ ( t ) ) , where λ is a (large) base frequency, the phase φ ( t ) is time-varying and the amplitude A ( t ) is slowly varying. Given a set of noisy measurements, we would like to test whether there is signal or whether the data is just noise. One particular application of note in conjunction with this problem is the detection of gravitational waves predicted by Einstein's Theory of General Relativity. We introduce detection strategies which are very sensitive and more flexible than existing feature detectors. The idea is to use structured algorithms which exploit information in the so-called chirplet graph to chain chirplets together adaptively as to form chirps with polygonal instantaneous frequency. We then search for the path in the graph which provides the best trade-off between complexity and goodness of fit. Underlying our methodology is the idea that while the signal may be extremely weak so that none of the individual empirical coefficients is statistically significant, one can still reliably detect by combining several coefficients into a coherent chain. This strategy is general and may be applied in many other detection problems. We complement our study with numerical experiments showing that our algorithms are so sensitive that they seem to detect signals whenever their strength makes them detectable by any method.
AbstractList	This paper considers the problem of detecting nonstationary phenomena, and chirps in particular, from very noisy data. Chirps are waveforms of the very general form A ( t ) exp ( ı λ φ ( t ) ) , where λ is a (large) base frequency, the phase φ ( t ) is time-varying and the amplitude A ( t ) is slowly varying. Given a set of noisy measurements, we would like to test whether there is signal or whether the data is just noise. One particular application of note in conjunction with this problem is the detection of gravitational waves predicted by Einstein's Theory of General Relativity. We introduce detection strategies which are very sensitive and more flexible than existing feature detectors. The idea is to use structured algorithms which exploit information in the so-called chirplet graph to chain chirplets together adaptively as to form chirps with polygonal instantaneous frequency. We then search for the path in the graph which provides the best trade-off between complexity and goodness of fit. Underlying our methodology is the idea that while the signal may be extremely weak so that none of the individual empirical coefficients is statistically significant, one can still reliably detect by combining several coefficients into a coherent chain. This strategy is general and may be applied in many other detection problems. We complement our study with numerical experiments showing that our algorithms are so sensitive that they seem to detect signals whenever their strength makes them detectable by any method.
Author	Charlton, Philip R. Candès, Emmanuel J. Helgason, Hannes
Author_xml	– sequence: 1 givenname: Emmanuel J. surname: Candès fullname: Candès, Emmanuel J. email: emmanuel@acm.caltech.edu organization: Applied and Computational Mathematics, Caltech, Pasadena, CA 91125, USA – sequence: 2 givenname: Philip R. surname: Charlton fullname: Charlton, Philip R. organization: School of Computing and Mathematics, Charles Sturt University, Wagga Wagga, NSW 2678, Australia – sequence: 3 givenname: Hannes surname: Helgason fullname: Helgason, Hannes organization: Applied and Computational Mathematics, Caltech, Pasadena, CA 91125, USA
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Keywords	Adaptivity Shortest path in a graph Likelihood ratios Nonparametric testing Gravitational waves Graphs Time–frequency analysis Dynamic programming Chirplets Signal detection Chirps
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Snippet	This paper considers the problem of detecting nonstationary phenomena, and chirps in particular, from very noisy data. Chirps are waveforms of the very general...
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SubjectTerms	Adaptivity Chirplets Chirps Dynamic programming Graphs Gravitational waves Likelihood ratios Nonparametric testing Shortest path in a graph Signal detection Time–frequency analysis
Title	Detecting highly oscillatory signals by chirplet path pursuit
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