Title :
Noise Attenuation for 2-D Seismic Data by Radial-Trace Time-Frequency Peak Filtering
Author :
Wu, Ning ; Li, Yue ; Yang, Baojun
Author_Institution :
Dept. of Commun. Eng., Jilin Univ., Changchun, China
Abstract :
The time-frequency peak filtering (TFPF) is an effective tool in random-noise attenuation and has been applied to seismic record denoising in recent years. The window length (WL) of the time-frequency distribution (TFD) is the key to the conventional TFPF technology. A fixed WL is not optimal for both the low- and high-frequency components at the same time; an adaptive WL results in serious distortion of the reflected waveform. In this letter, we discuss a modified TFPF along the radial-trace direction and prove its advantage in TFD window selection. Experiments on both synthetic models and field data show that the radial-trace TFPF result is no longer much influenced by the WL as the conventional TFPF. Furthermore, it can provide better performance in both random-noise attenuation and reflected signal preservation with a fixed WL.
Keywords :
geophysical signal processing; geophysical techniques; random noise; seismology; signal denoising; time-frequency analysis; TFD window selection; adaptive WL; conventional TFPF technology; radial-trace TFPF; radial-trace direction; radial-trace time-frequency peak filtering; random-noise attenuation; reflected signal preservation; reflected waveform; seismic data denoising; seismic record denoising; time-frequency distribution; window length; Attenuation; Linearity; Noise reduction; Signal to noise ratio; Time frequency analysis; Transforms; Radial-trace time-frequency peak filtering (TFPF); seismic data denoising; time-frequency distribution (TFD); window length (WL);
Journal_Title :
Geoscience and Remote Sensing Letters, IEEE
DOI :
10.1109/LGRS.2011.2129552
