Reconstruction of Dispersion Curves in the Frequency-Wavenumber Domain Using Compressed Sensing on a Random Array

Drémeau, Angélique; Courtois, Florent Le; Bonnel, Julien

doi:10.1109/joe.2016.2644780

Cited by 28 publications

(16 citation statements)

References 36 publications

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“…In shallow-water environments, the vertical wavenumbers k zm weakly depend on the frequency [9]; the quantity is thus smaller than the other terms of the equation and can be neglected. Dispersive relation has been exploited to track the propagating wavenumbers in the (f-k) diagram in [7] and [8]. We place this work in the continuation of these previous contributions, but in contrast to them, we propose here a method where wavenumbers are not constrained to lie on a discrete grid and that does not require prior knowledge of the modal cut-off frequencies (as in [7]).…”

Section: Acoustic Propagation In Dispersive Shallow Water Environmentsmentioning

confidence: 99%

“…To overcome this problem, we propose to account for the sparsity of the contribution of modes in the spatial spectra. In addition, based on ideas introduced in previous works [7,8], which explicit prior information on both the number of modes expected to propagate at each frequency and their links from one frequency to another, we address mode tracking among spatial spectra at successive time frequencies. Our contribution goes beyond these works : in addition to taking into account physical priors, we propose an algorithm that is free of the constraint of grid search for the wavenumber estimation.…”

Section: Introductionmentioning

confidence: 99%

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Dispersive Grid-free Orthogonal Matching Pursuit for Modal Estimation in Ocean Acoustics

Paviet-Salomon

Dorffer

Bonnel

et al. 2020

ICASSP 2020 - 2020 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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Considering low-frequency acoustic sources, shallowwater environments act as modal dispersive waveguides. In this context, the signal can be described as a sum of a few modal components, each of them propagating with its own wavenumber. When dealing with broadband sources, wavenumber-frequency (f-k) diagrams constitute popular representations naturally enabling modal separation. Based on a Fourier transform, they require however a large number of sensors to resolve wavenumbers with a high-resolution. This limitation can be overcame by adding some physical priors to the processing method. In the continuation of previous works, we propose here a new grid-free algorithm allowing a super-resolution of the (f-k) diagram by benifiting from the sparse nature of the wavenumber spectrum and embedding the broadband behavior of the wavenumbers within the algorithm. The method is validated on simulated data.

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Section: Acoustic Propagation In Dispersive Shallow Water Environmentsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dispersive Grid-free Orthogonal Matching Pursuit for Modal Estimation in Ocean Acoustics

Paviet-Salomon

Dorffer

Bonnel

et al. 2020

ICASSP 2020 - 2020 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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“…We then use sparse wavenumber synthesis to generate a model. These techniques have also been adapted for underwater acoustics [44] and medical diagnostics [45]. Recent advances [44], [46] have also introduced optimization constraints to improve the effectiveness of sparse wavenumber analysis.…”

Section: Part Ii: Addressing Uncertaintymentioning

confidence: 99%

Managing Complexity, Uncertainty, and Variability in Guided Wave Structural Health Monitoring

Harley

Liu

Oppenheim

et al. 2017

SICE Journal of Control, Measurement, and System Integration

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: Guided waves are an attractive tool for monitoring large structures. They are able to interrogate sizable areas at once, are sensitive to structural damage, and carry information about the damage location. Yet, there are many challenges to guided wave data analysis. First, guided waves are represented by a complex set of dispersive wave modes that distort their shape and phase as they travel through the medium. Second, the complex properties of guided waves are often unknown. Third, the unknown properties often vary as a function of time. As a result, to effectively analyze guided waves, their complex properties must be learned, tracked, and leveraged. This paper describes signal processing tools for managing the complexity, uncertainty, and variability of guided waves for structural health monitoring applications. We use a stretch-based and a matrix decomposition based temperature compensation methods to handle variability, sparse wavenumber analysis to learn the uncertain properties of guided waves, and matched field processing to then leverage these complexities. We demonstrate how these methods are combined for effective guided wave data analysis with experimental data from an aluminum plate under varying temperature conditions.

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“…Thus, in order to reduce the redundant geophones used in conventional measurements, this paper contributes to this objective by exploring a novel in-site technique based on compressive sensing (CS) to reduce the number of required geophone and measurements for the estimation of surface wave velocity of the subsoil. CS has been applied to recover the multimodal and dispersive properties of Lamb wave from observed data in the laboratory for analysis, reconstruction, and prediction of guided waves [14][15][16][17][18][19][20]. Jiang et al applied CS to ultrasonic computerized tomography to reduce observation times for estimation of a steel tube slab structure [21,22].…”

Section: Introductionmentioning

confidence: 99%

Accurate Sparse Recovery of Rayleigh Wave Characteristics Using Fast Analysis of Wave Speed (FAWS) Algorithm for Soft Soil Layers

et al. 2018

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This paper presents a novel fast analysis of wave speed (FAWS) algorithm from the waveforms recorded by a random-spaced geophone array based on a compressive sensing (CS) platform. Rayleigh-type seismic surface wave testing is excited by a hammer source and conducted to develop the phase velocity characteristics of the subsoil layers in Shenyang Metro line 9. Data are filtered by a bandpass filter bank to pursue the dispersive profiles of phase velocity at various frequencies. The Rayleigh-type surface-wave dispersion curve for the soil layers at each frequency is conducted by the 1 -norm minimization algorithm of CS theory. The traditional frequency-wavenumber transform technique and in-site downhole observation are employed as the comparison of the proposed technique. The experimental results indicate the proposed FAWS algorithm has a good agreement with both the results of conventional even-spaced geophone array and the in-site measurements, which provides an effective and efficient way for accurate non-destructive evaluation of the surface wave dispersion curve of the soil.

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Reconstruction of Dispersion Curves in the Frequency-Wavenumber Domain Using Compressed Sensing on a Random Array

Cited by 28 publications

References 36 publications

Dispersive Grid-free Orthogonal Matching Pursuit for Modal Estimation in Ocean Acoustics

Dispersive Grid-free Orthogonal Matching Pursuit for Modal Estimation in Ocean Acoustics

Managing Complexity, Uncertainty, and Variability in Guided Wave Structural Health Monitoring

Accurate Sparse Recovery of Rayleigh Wave Characteristics Using Fast Analysis of Wave Speed (FAWS) Algorithm for Soft Soil Layers

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