Retraction: Lin, G.-W., et al. Reconstructing the Dynamic Processes of the Taimali Landslide in Taiwan Using the Waveform Inversion Method. Appl. Sci. 2020, 10, 5872

Guan-Wei Lin; Ching Hung

doi:10.3390/app11031192

Retraction: Lin, G.-W., et al. Reconstructing the Dynamic Processes of the Taimali Landslide in Taiwan Using the Waveform Inversion Method. Appl. Sci. 2020, 10, 5872

Applied Sciences ◽

10.3390/app11031192 ◽

2021 ◽

Vol 11 (3) ◽

pp. 1192

Author(s):

Guan-Wei Lin ◽

Ching Hung

Keyword(s):

Waveform Inversion ◽

Dynamic Processes ◽

Inversion Method

The authors and journal retract the article, “Reconstructing the Dynamic Processes of the Taimali Landslide in Taiwan Using the Waveform Inversion Method” [...]

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Reconstructing the Dynamic Processes of the Taimali Landslide in Taiwan Using the Waveform Inversion Method

Applied Sciences ◽

10.3390/app10175872 ◽

2020 ◽

Vol 10 (17) ◽

pp. 5872

Author(s):

Guan-Wei Lin ◽

Ching Hung

Keyword(s):

Waveform Inversion ◽

Time Function ◽

Dynamic Processes ◽

Inversion Method ◽

Runout Distance ◽

Digital Elevation ◽

Single Station ◽

Force Time ◽

Elevation Model ◽

Inversion Techniques

As a landslide occurs, seismic signals generated by the mass sliding on the slope can be recorded by seismometers nearby. Using waveform inversion techniques, we can explore the dynamic processes (e.g., sliding direction, velocity, and runout distance) of a landslide with the inverted force–time function. In this study, the point force history (PFH) inversion method was applied to the Taimali landslide in Taiwan, which was triggered by a heavy rainstorm in 2009. The inverted force–time function for the landslide revealed the complicated dynamic processes. The time series of velocity indicated three different sliding directions during the landslide. Hence, three propagating stages of the Taimali landslide were determined and were consistent with an investigation using remote sensing images and a digital elevation model of the landslide. In addition, the PFH inversion was implemented using high-quality single-station records and maintained good performance compared with the inversion by multistation records.

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Application of an Improved Ultrasound Full-Waveform Inversion in Bone Quantitative Measurement

Symmetry ◽

10.3390/sym13020260 ◽

2021 ◽

Vol 13 (2) ◽

pp. 260

Author(s):

Meng Suo ◽

Dong Zhang ◽

Yan Yang

Keyword(s):

Nonlinear Equations ◽

Waveform Inversion ◽

Optimal Solution ◽

Inversion Method ◽

Full Waveform Inversion ◽

Inversion Algorithm ◽

Elastic Wave Equation ◽

Full Waveform ◽

Ultrasonic Propagation ◽

Joint Velocity

Inspired by the large number of applications for symmetric nonlinear equations, an improved full waveform inversion algorithm is proposed in this paper in order to quantitatively measure the bone density and realize the early diagnosis of osteoporosis. The isotropic elastic wave equation is used to simulate ultrasonic propagation between bone and soft tissue, and the Gauss–Newton algorithm based on symmetric nonlinear equations is applied to solve the optimal solution in the inversion. In addition, the authors use several strategies including the frequency-grid multiscale method, the envelope inversion and the new joint velocity–density inversion to improve the result of conventional full-waveform inversion method. The effects of various inversion settings are also tested to find a balanced way of keeping good accuracy and high computational efficiency. Numerical inversion experiments showed that the improved full waveform inversion (FWI) method proposed in this paper shows superior inversion results as it can detect small velocity–density changes in bones, and the relative error of the numerical model is within 10%. This method can also avoid interference from small amounts of noise and satisfy the high precision requirements for quantitative ultrasound measurements of bone.

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Traveltime information-based wave-equation inversion

Geophysics ◽

10.1190/1.3243073 ◽

2009 ◽

Vol 74 (6) ◽

pp. WCC27-WCC36 ◽

Cited By ~ 30

Author(s):

Yu Zhang ◽

Daoliu Wang

Keyword(s):

Wave Equation ◽

Conventional Method ◽

Seismic Data ◽

Waveform Inversion ◽

Back Propagation ◽

Velocity Model ◽

Data Fitting ◽

Inversion Method ◽

New Wave ◽

Seismic Record

We propose a new wave-equation inversion method that mainly depends on the traveltime information of the recorded seismic data. Unlike the conventional method, we first apply a [Formula: see text] transform to the seismic data to form the delayed-shot seismic record, back propagate the transformed data, and then invert the velocity model by maximizing the wavefield energy around the shooting time at the source locations. Data fitting is not enforced during the inversion, so the optimized velocity model is obtained by best focusing the source energy after a back propagation. Therefore, inversion accuracy depends only on the traveltime information embedded in the seismic data. This method may overcome some practical issues of waveform inversion; in particular, it relaxes the dependency of the seismic data amplitudes and the source wavelet.

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Source-independent extended waveform inversion based on space-time source extension: Frequency-domain implementation

Geophysics ◽

10.1190/geo2017-0333.1 ◽

2018 ◽

Vol 83 (5) ◽

pp. R449-R461 ◽

Cited By ~ 5

Author(s):

Guanghui Huang ◽

Rami Nammour ◽

William W. Symes

Keyword(s):

Source Function ◽

Random Noise ◽

A Priori ◽

Waveform Inversion ◽

Low Frequency ◽

Inversion Method ◽

Target Velocity ◽

Extended Source ◽

Full Waveform ◽

Time Variables

Source signature estimation from seismic data is a crucial ingredient for successful application of seismic migration and full-waveform inversion (FWI). If the starting velocity deviates from the target velocity, FWI method with on-the-fly source estimation may fail due to the cycle-skipping problem. We have developed a source-based extended waveform inversion method, by introducing additional parameters in the source function, to solve the FWI problem without the source signature as a priori. Specifically, we allow the point source function to be dependent on spatial and time variables. In this way, we can easily construct an extended source function to fit the recorded data by solving a source matching subproblem; hence, it is less prone to cycle skipping. A novel source focusing annihilator, defined as the distance function from the real source position, is used for penalizing the defocused energy in the extended source function. A close data fit avoiding the cycle-skipping problem effectively makes the new method less likely to suffer from local minima, which does not require extreme low-frequency signals in the data. Numerical experiments confirm that our method can mitigate cycle skipping in FWI and is robust against random noise.

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