3-D coherency filtering

Coherency filtering is a tool used commonly in 2-D seismic processing to isolate desired events from noisy data. It assumes that phase‐coherent signal can be separated from background incoherent noise on the basis of coherency estimates, and coherent noise from coherent signal on the basis of different dips. It is achieved by searching for the maximum coherence direction for each data point of a seismic event and enhancing the event along this direction through stacking; it suppresses the incoherent events along other directions. Foundations for a 2-D coherency filtering algorithm were laid out by several researchers (Neidell and Taner, 1971; McMechan, 1983; Leven and Roy‐Chowdhury, 1984; Kong et al., 1985; Milkereit and Spencer, 1989). Milkereit and Spencer (1989) have applied 2-D coherency filtering successfully to 2-D deep crustal seismic data for the improvement of visualization and interpretation. Work on random noise attenuation using frequency‐space or time‐space prediction filters both in two or three dimensions to increase the signal‐to‐noise ratio of the data can be found in geophysical literature (Canales, 1984; Hornbostel, 1991; Abma and Claerbout, 1995).

Download Full-text

5D de-aliased seismic data interpolation using non-stationary prediction error filter

Geophysics ◽

10.1190/geo2020-0540.1 ◽

2021 ◽

pp. 1-92

Author(s):

Yangkang Chen ◽

Sergey Fomel ◽

Hang Wang ◽

shaohuan zu

Keyword(s):

Seismic Data ◽

Prediction Error ◽

Reduction Method ◽

Signal To Noise Ratio ◽

Data Interpolation ◽

Computationally Efficient ◽

Rank Reduction ◽

Frequency Space ◽

Time Space ◽

Ill Posed

The prediction error filter (PEF) assumes that the seismic data can be destructed to zero by applying a convolutional operation between the target data and prediction filter in either time-space or frequency-space domain. Here, we extend the commonly known PEF in 2D or 3D problems to its 5D version. To handle the non-stationary property of the seismic data, we formulate the PEF in a non-stationary way, which is called the non-stationary prediction error filter (NPEF). In the NPEF, the coefficients of a fixed-size PEF vary across the whole seismic data. In NPEF, we aim at solving a highly ill-posed inverse problem via the computationally efficient iterative shaping regularization. The NPEF can be used to denoise multi-dimensional seismic data, and more importantly, to restore the highly incomplete aliased 5D seismic data. We compare the proposed NPEF method with the state-of-the-art rank-reduction method for the 5D seismic data interpolation in cases of irregularly and regularly missing traces via several synthetic and real seismic data. Results show that although the proposed NPEF method is less effective than the rank-reduction method in interpolating irregularly missing traces especially in the case of low signal to noise ratio (S/N), it outperforms the rank-reduction method in interpolating aliased 5D dataset with regularly missing traces.

Download Full-text

Non-stationary predictive filtering for seismic random noise suppression - A tutorial

Geophysics ◽

10.1190/geo2020-0368.1 ◽

2021 ◽

pp. 1-79 ◽

Cited By ~ 1

Author(s):

Hang Wang ◽

Wei Chen ◽

Weilin Huang ◽

Shaohuan Zu ◽

Xingye Liu ◽

...

Keyword(s):

Seismic Data ◽

Space Dimension ◽

Noise Suppression ◽

Random Noise ◽

Spatial Dimension ◽

Seismic Data Processing ◽

Filtering Method ◽

Time Space ◽

Stationary Version ◽

Predictive Filtering

Predictive filtering in the frequency domain is one of the most widely used denoising algorithms in the seismic data processing workflow. Predictive filtering is based on the assumption of linear/planar events in the time-space domain. In traditional predictive filtering method, the predictive filter is fixed across the spatial dimension, which cannot deal with the spatial variation of seismic data well. To handle the curving events, the predictive filter is either applied in local windows or extended to a non-stationary version. The regularized non-stationary autoregression (RNAR) method can be treated as a non-stationary extension of the traditional predictive filtering, where the predictive filter coefficients are variable in different space locations. The highly under-determined inverse problem is solved by shaping regularization with a smoothness constraint in space. We further extend the RNAR method to a more general case, where we can apply more constraints to the filter coefficients according to the features of seismic data. First, apart from the smoothness in space, we also apply a smoothing constraint in frequency, considering the coherency of the coefficients in the frequency dimension. Secondly, we apply a frequency dependent smoothing radius along the space dimension to better take advantage of the non-stationarity of seismic data in the frequency axis, and to better deal with noise. The proposed method is validated via several synthetic and field data examples.

Download Full-text

ROBUST SVD FILTERING FOR LOW SIGNAL-TO-NOISE RATIO SEISMIC DATA

Geophysics ◽

10.1190/geo2020-0169.1 ◽

2021 ◽

pp. 1-51

Author(s):

Chao Wang ◽

Yun Wang

Keyword(s):

Seismic Data ◽

Signal To Noise Ratio ◽

Singular Values ◽

New Method ◽

Signal To Noise ◽

Coherent Noise ◽

Edge Preserving ◽

Singular Vectors ◽

Reduced Rank ◽

Noise Ratio

Reduced-rank filtering is a common method for attenuating noise in seismic data. As conventional reduced-rank filtering distinguishes signals from noises only according to singular values, it performs poorly when the signal-to-noise ratio is very low, or when data contain high levels of isolate or coherent noise. Therefore, we developed a novel and robust reduced-rank filtering based on the singular value decomposition in the time-space domain. In this method, noise is recognized and attenuated according to the characteristics of both singular values and singular vectors. The left and right singular vectors corresponding to large singular values are selected firstly. Then, the right singular vectors are classified into different categories according to their curve characteristics, such as jump, pulse, and smooth. Each kind of right singular vector is related to a type of noise or seismic event, and is corrected by using a different filtering technology, such as mean filtering, edge-preserving smoothing or edge-preserving median filtering. The left singular vectors are also corrected by using the filtering methods based on frequency attributes like main-frequency and frequency bandwidth. To process seismic data containing a variety of events, local data are extracted along the local dip of event. The optimal local dip is identified according to the singular values and singular vectors of the data matrices that are extracted along different trial directions. This new filtering method has been applied to synthetic and field seismic data, and its performance is compared with that of several conventional filtering methods. The results indicate that the new method is more robust for data with a low signal-to-noise ratio, strong isolate noise, or coherent noise. The new method also overcomes the difficulties associated with selecting an optimal rank.

Download Full-text

Multichannel absorption compensation with a data-driven structural regularization

Geophysics ◽

10.1190/geo2019-0132.1 ◽

2019 ◽

Vol 85 (1) ◽

pp. V71-V80 ◽

Cited By ~ 1

Author(s):

Xiong Ma ◽

Guofa Li ◽

Hao Li ◽

Wuyang Yang

Keyword(s):

Cost Function ◽

Structural Characteristic ◽

Seismic Data ◽

High Frequency ◽

Signal To Noise Ratio ◽

Random Noise ◽

Frequency Noise ◽

Characteristic Operator ◽

High Frequency Noise ◽

The Cost

Seismic absorption compensation is an important processing approach to mitigate the attenuation effects caused by the intrinsic inelasticity of subsurface media and to enhance seismic resolution. However, conventional absorption compensation approaches ignore the spatial connection along seismic traces, which makes the compensation result vulnerable to high-frequency noise amplification, thus reducing the signal-to-noise ratio (S/N) of the result. To alleviate this issue, we have developed a structurally constrained multichannel absorption compensation (SC-MAC) algorithm. In the cost function of this algorithm, we exploit an [Formula: see text] norm to constrain the reflectivity series and an [Formula: see text] norm to regularize the reflection structural characteristic of the compensation data. The reflection structural characteristic operator, extracted from the observed stacked seismic data, is the core of the structural regularization term. We then solve the cost function of SC-MAC by the alternating direction method of multipliers. Benefiting from the introduction of reflection structure constraint, SC-MAC improves the stability of the compensation result and inhibits the amplification of high-frequency noise. Synthetic and field data examples demonstrate that our proposed method is more robust to random noise and can not only improve the resolution of seismic data, but also maintain the S/N of the compensation seismic data.

Download Full-text

Random denoising and signal nonlinearity approach by time-frequency peak filtering using weighted frequency reassignment

Geophysics ◽

10.1190/geo2012-0432.1 ◽

2013 ◽

Vol 78 (6) ◽

pp. V229-V237 ◽

Cited By ~ 27

Author(s):

Hongbo Lin ◽

Yue Li ◽

Baojun Yang ◽

Haitao Ma

Keyword(s):

Weight Function ◽

Instantaneous Frequency ◽

Seismic Data ◽

Signal To Noise Ratio ◽

Random Noise ◽

Signal To Noise ◽

Transform Method ◽

Time Frequency ◽

Frequency Peak ◽

Noise Ratio

Time-frequency peak filtering (TFPF) may efficiently suppress random noise and hence improve the signal-to-noise ratio. However, the errors are not always satisfactory when applying the TFPF to fast-varying seismic signals. We begin with an error analysis for the TFPF by using the spread factor of the phase and cumulants of noise. This analysis shows that the nonlinear signal component and non-Gaussian random noise lead to the deviation of the pseudo-Wigner-Ville distribution (PWVD) peaks from the instantaneous frequency. The deviation introduces the signal distortion and random oscillations in the result of the TFPF. We propose a weighted reassigned smoothed PWVD with less deviation than PWVD. The proposed method adopts a frequency window to smooth away the residual oscillations in the PWVD, and incorporates a weight function in the reassignment which sharpens the time-frequency distribution for reducing the deviation. Because the weight function is determined by the lateral coherence of seismic data, the smoothed PWVD is assigned to the accurate instantaneous frequency for desired signal components by weighted frequency reassignment. As a result, the TFPF based on the weighted reassigned PWVD (TFPF_WR) can be more effective in suppressing random noise and preserving signal as compared with the TFPF using the PWVD. We test the proposed method on synthetic and field seismic data, and compare it with a wavelet-transform method and [Formula: see text] prediction filter. The results show that the proposed method provides better performance over the other methods in signal preserving under low signal-to-noise ratio.

Download Full-text

A 1D time-varying median filter for seismic random, spike-like noise elimination

Geophysics ◽

10.1190/1.3043446 ◽

2009 ◽

Vol 74 (1) ◽

pp. V17-V24 ◽

Cited By ~ 64

Author(s):

Yang Liu ◽

Cai Liu ◽

Dian Wang

Keyword(s):

Seismic Data ◽

Signal To Noise Ratio ◽

Median Filter ◽

Random Noise ◽

Threshold Value ◽

Band Pass Filter ◽

Time Varying ◽

Noise Elimination ◽

Pass Filter ◽

Median Filters

Random noise in seismic data affects the signal-to-noise ratio, obscures details, and complicates identification of useful information. We have developed a new method for reducing random, spike-like noise in seismic data. The method is based on a 1D stationary median filter (MF) — the 1D time-varying median filter (TVMF). We design a threshold value that controls the filter window according to characteristics of signal and random, spike-like noise. In view of the relationship between seismic data and the threshold value, we chose median filters with different time-varying filter windows to eliminate random, spike-like noise. When comparing our method with other common methods, e.g., the band-pass filter and stationary MF, we found that the TVMF strikes a balance between eliminating random noise and protecting useful information. We tested the feasibility of our method in reducing seismic random, spike-like noise, on a synthetic dataset. Results of applying the method to seismic land data from Texas demonstrated that the TVMF method is effective in practice.

Download Full-text

Random noise attenuation using f-x regularized nonstationary autoregression

Geophysics ◽

10.1190/geo2011-0117.1 ◽

2012 ◽

Vol 77 (2) ◽

pp. V61-V69 ◽

Cited By ~ 89

Author(s):

Guochang Liu ◽

Xiaohong Chen ◽

Jing Du ◽

Kailong Wu

Keyword(s):

Seismic Data ◽

Random Noise ◽

Geological Structure ◽

Least Square ◽

Noise Attenuation ◽

Spatial Direction ◽

Random Noise Attenuation ◽

Time Space ◽

Prediction Technique ◽

Domain Prediction

We have developed a novel method for random noise attenuation in seismic data by applying regularized nonstationary autoregression (RNA) in the frequency-space ([Formula: see text]) domain. The method adaptively predicts the signal with spatial changes in dip or amplitude using [Formula: see text] RNA. The key idea is to overcome the assumption of linearity and stationarity of the signal in conventional [Formula: see text] domain prediction technique. The conventional [Formula: see text] domain prediction technique uses short temporal and spatial analysis windows to cope with the nonstationary of the seismic data. The new method does not require windowing strategies in spatial direction. We implement the algorithm by an iterated scheme using the conjugate-gradient method. We constrain the coefficients of nonstationary autoregression (NA) to be smooth along space and frequency in the [Formula: see text] domain. The shaping regularization in least-square inversion controls the smoothness of the coefficients of [Formula: see text] RNA. There are two key parameters in the proposed method: filter length and radius of shaping operator. Tests on synthetic and field data examples showed that, compared with [Formula: see text] domain and time-space domain prediction methods, [Formula: see text] RNA can be more effective in suppressing random noise and preserving the signals, especially for complex geological structure.

Download Full-text

Stacking seismic data using local correlation

Geophysics ◽

10.1190/1.3085643 ◽

2009 ◽

Vol 74 (3) ◽

pp. V43-V48 ◽

Cited By ~ 101

Author(s):

Guochang Liu ◽

Sergey Fomel ◽

Long Jin ◽

Xiaohong Chen

Keyword(s):

Seismic Data ◽

Field Data ◽

Signal To Noise Ratio ◽

Random Noise ◽

Image Point ◽

Local Correlation ◽

Seismic Profiles ◽

Signal To Noise ◽

Prestack Migration

Stacking plays an important role in improving signal-to-noise ratio and imaging quality of seismic data. However, for low-fold-coverage seismic profiles, the result of conventional stacking is not always satisfactory. To address this problem, we have developed a method of stacking in which we use local correlation as a weight for stacking common-midpoint gathers after NMO processing or common-image-point gathers after prestack migration. Application of the method to synthetic and field data showed that stacking using local correlation can be more effective in suppressing random noise and artifacts than other stacking methods.

Download Full-text

Random noise attenuation by planar mathematical morphological filtering

Geophysics ◽

10.1190/geo2017-0288.1 ◽

2018 ◽

Vol 83 (1) ◽

pp. V11-V25 ◽

Cited By ~ 7

Author(s):

Weilin Huang ◽

Runqiu Wang

Keyword(s):

Seismic Data ◽

Signal To Noise Ratio ◽

Random Noise ◽

Seismic Exploration ◽

Noise Attenuation ◽

Seismic Waveforms ◽

Morphological Filtering ◽

Alternative Techniques ◽

The Difference ◽

The Relationship

Improving the signal-to-noise ratio (S/N) of seismic data is desirable in many seismic exploration areas. The attenuation of random noise can help to improve the S/N. Geophysicists usually use the differences between signal and random noise in certain attributes, such as frequency, wavenumber, or correlation, to suppress random noise. However, in some cases, these differences are too small to be distinguished. We used the difference in planar morphological scales between signal and random noise to separate them. The planar morphological scale is the information that describes the regional shape of seismic waveforms. The attenuation of random noise is achieved by removing the energy in the smaller morphological scales. We call our method planar mathematical morphological filtering (PMMF). We analyze the relationship between the performance of PMMF and its input parameters in detail. Applications of the PMMF method to synthetic and field post/prestack seismic data demonstrate good performance compared with competing alternative techniques.

Download Full-text

Parallel Frequency Acquisition Algorithm for BeiDou Software Receiver Based on Coherent Downsampling

Journal of Navigation ◽

10.1017/s0373463319000699 ◽

2019 ◽

Vol 73 (2) ◽

pp. 433-454

Author(s):

Qingxi Zeng ◽

Chang Gao ◽

Wenqi Qiu ◽

Zhaihe Zhou ◽

Chade Lyu

Keyword(s):

Signal To Noise Ratio ◽

Random Noise ◽

Satellite System ◽

Frequency Space ◽

Satellite Signal ◽

Parallel Code ◽

Initial Sampling ◽

Global Navigation Satellite ◽

Down Conversion ◽

Band Signal

The time it takes to acquire a satellite signal is one of the most important parameters for a Global Navigation Satellite System (GNSS) receiver. The Parallel Frequency space search acquisition Algorithm (PFA) runs faster than the Parallel Code phase search acquisition Algorithm (PCA) when the approximate phase of Pseudo-Random Noise (PRN) code and the approximate value of a Doppler shift are known. However, a large amount of data is needed to be dealt with by the Fast Fourier Transform (FFT) in a traditional PFA algorithm because it processes a narrow-band signal with the initial sampling frequency after the PRN code is stripped. In order to reduce the computational complexity of the traditional PFA algorithm, a down-conversion module and a downsampling module were added to the traditional PFA in the work reported here. Experiments demonstrated that this method not only succeeded in acquiring BeiDou B1I signals, but also the time for acquirement was reduced by at least 80% with the modified PFA algorithm compared with the traditional PFA algorithm. The loss in Signal-to-Noise Ratio (SNR) did not exceed 0·5 dB when the number of coherent points was less than 500.

Download Full-text