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Abstrakty
In seismic data from areas with low-velocity structures, a special type of multiple reflected refraction often appears, which seriously affects the effective refection wave of adjacent target layers and causes distortion of the refection wave shape. Based on the kinematic characteristics of the seismic wave field in shallow low-velocity zones, we demonstrate the generation mechanism of multiple reflected refractions. Then, a method of suppressing multiple reflected refractions through vertically combined dual sources is proposed. First, according to the relative position relationship between multiple reflection refractions and the effective wave, prerequisites for the suppression of multiple reflected refractions are established. Second, the optional range of vertical combination parameters is calculated according to the source combination equation, which is used to adjust the relative position of the two sources set vertically in the low-velocity zone. Subsequently, model data verification and application of the Loess Plateau exploration area prove that the vertical source combination method can suppress multiple reflected refractions in shallow low-velocity zones and effectively improve the signal-to-noise ratio of seismic data.
Wydawca
Czasopismo
Rocznik
Tom
Strony
1799--1811
Opis fizyczny
Bibliogr. 24 poz.
Twórcy
autor
- Department of Earth Science & Engineering, Taiyuan University of Technology, Taiyuan, China
autor
- Department of Earth Science & Engineering, Taiyuan University of Technology, Taiyuan, China
autor
- Department of Earth Science & Engineering, Taiyuan University of Technology, Taiyuan, China
autor
- Shanxi Earthquake Agency, Taiyuan, China
autor
- Department of Earth Science & Engineering, Taiyuan University of Technology, Taiyuan, China
Bibliografia
- 1. Cerveny V (1971) Theory of Seismic Head Waves. Univ. of Toronto Pr
- 2. Chang S, Li L, Zhang Y et al (2002) (2002) A study of coalfield seismic exploration method in thick-loess covered hills areas. Geophys Geochem Explor 6:425–428 ((in Chinese))
- 3. Chen Q, Chang S, Fan G et al (2010) Research on key techniques for coalfield seismic data acquisition in thick loess area. Coal Geol Explor 38(4):59–64 ((in Chinese))
- 4. Dai X, Xu Y, Gan L et al (2019) Deep & ultra-deep multiple suppression in Central Sichuan: an example of Gaoshiti-Moxi. Oil Geophys Prospect 54(1):54–64 ((in Chinese))
- 5. Guo C (2011) Study on propagation characteristics of multiple reflected refractions in complex surface layers. China University of Petroleum, China ((in Chinese))
- 6. Hemon CH, Mace D (1978) Use of the Karhunen-Loeve transformation in seismic data-processing. Geophys Prospect 26(3):600–626
- 7. Hong F, Hu T, Zhang W et al (2004) Attenuating multiples for low signal-to-noise ratio seismic data using optimal beamforming. Chin J Geophys 47(6):1106–1110 ((in Chinese))
- 8. Hu Y, Liu D, Wang X, Zhao Z et al (2021) Attenuation of the multiple reflection-refraction in 2-d common-shot gather via random-derangement-based fx cadzow filter. IEEE Geosci Remote Sens Lett 99:1–5
- 9. Knapp RW, Steeples DW (1986) High-resolution common-depth-point reflection profiling: field acquisition parameter design. Geophysics 51(2):283–294
- 10. Li Q (1983) On the secondary interference of earthquake-Also on the Improvement direction of seismic record in difficult areas. Oil Geophys Prospect 18(3):207–225 ((in Chinese))
- 11. Liang C (1993) Analyzing and eliminating multiple reflected refractions. Geophys Prospect Pet 32(3):112–118
- 12. Lin TY, Herrmann FJ (2013) Robust estimation of primaries by sparse inversion via one-norm minimization. Geophysics 78(3):133–150
- 13. Liu SW (1981) The review of seismic exploration the western part of Hua-Bei Basin[J]. Oil Geophys Prospect 16(1):1–17
- 14. Plasterie P, Gayne M, Lange M, et al. (2008) Shallow water 3D surface-related multiple modelling, case study. Seg Technical Program Expanded
- 15. Qin Z (1990) (1990) Analysis of seismic noises in the DQ area. Oil Geophys Prospect 1:86–102 ((in Chinese))
- 16. Sheriff RE (1995) Exploration seismology Seismology. Cambridge Press, Cambridge
- 17. Sinton JB, Ward RW, Watkins JS (1978) Suppression of long-delay multiple reflections by predictive deconvolution. Geophysics 43(7):1352–1367
- 18. Song J, Li P, Wang W et al (2019) High-productivity blended acquired data separation by sparse inversion. Oil Geophys Prospect 54(2):268–273 ((in Chinese))
- 19. Wang W, Jin H (2015) 3D surface-related multiple elimination based on sparse inversion. Chin J Geophys 58(7):2496–2507 ((in Chinese))
- 20. Weglein AB, Hsu S, Paolo T et al (2011) Multiple attenuation: recent advances and the road ahead. Lead Edge (tulsa, Ok) 30(8):864–875
- 21. Wu X (2014) High-fidelity adaptive curvelet domain primary-multiple separation processing of seismic data. CSIRO Publishing, Australia. https://doi.org/10.1071/ASEG2013ab094
- 22. Yang K, Guo C (2012) Propagation paths of multiple reflected refraction. Oil Geophys Prospect 47(3):379–384 ((in Chinese))
- 23. Ypma FHC, Verschuur DJ (2013) Estimating primaries by sparse inversion, a generalized approach. Geophys Prospect 61:94–108
- 24. Zhang S, Huang H, Dong Y et al (2017) Direct estimation of the fluid properties and brittleness via elastic impedance inversion for predicting sweet spots and the fracturing area in the unconventional reservoir. J Nat Gas Sci Eng 45:415–427
Typ dokumentu
Bibliografia
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