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No AccessGEOPHYSICSVolume 85, Issue 4

Joint inversion of logging-while-drilling multipole acoustic data to determine formation shear-wave transverse isotropy

Authors:
https://doi.org/10.1190/geo2019-0611.1

ABSTRACT

Seismic-wave anisotropy has long been an important topic in the exploration and development of unconventional reservoirs, especially in shales, which are commonly characterized as transversely isotropic ([TI] or vertical TI [VTI]) media. At present, the shear-wave (S-wave) TI properties have mainly been determined from monopole Stoneley- or dipole flexural-wave measurements in wireline acoustic logging, but the feasibility of those obtained from logging-while-drilling (LWD) acoustic data needs to be established. We have developed a joint inversion method for simultaneously determining formation S-wave transverse isotropy and vertical velocity from LWD multipole acoustic data. Our theoretical analysis shows that the presence of anisotropy strongly influences LWD Stoneley- and quadrupole-wave dispersion characteristics. Although the monopole Stoneley and quadrupole waves are sensitive to the formation S-wave TI parameters, they suffer from the typical nonuniqueness problem when using the individual-wave data to invert parameters alone. Thus, the respective dispersion data can be jointly used to estimate the formation S-wave TI properties. By the joint inversion, the nonuniqueness problem in the parameter inversion can also be effectively alleviated. The feasibility of the method has been verified by the processing results of theoretical synthetic data and field LWD acoustic-wave data. Therefore, the result offers an effective method for evaluating VTI formation anisotropy from acoustic LWD data.

REFERENCES

  • Briggs, V. A., 2006, A comparison of logging while drilling (LWD) and wireline acoustic measurements: Ph.D. thesis, Massachusetts Institute of Technology.
    Google Scholar
  • Cui, Z. W., 2004, Theoretical and numerical study of modified Biot’s models, acoustoelectric well logging and acoustic logging while drilling excited by multipole acoustic sources: Ph.D. thesis, Jilin University.
    Google Scholar
  • He, X., and H. S. Hu, 2009, Borehole flexural modes in transversely isotropic formations: Low-frequency asymptotic velocity: Geophysics, 74, no. 4, E149–E158, doi: 10.1190/1.3141442.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • He, X., H. S. Hu, and W. Guan, 2010, Fast and slow flexural waves in a deviated borehole in homogeneous and layered anisotropic formations: Geophysical Journal International, 181, 417–426, doi: 10.1111/j.1365-246X.2010.04503.x.GJINEA0956-540X
    Web of ScienceGoogle Scholar
  • Lee, S. Q., X. M. Tang, Y. D. Su, and C. X. Zhuang, 2016, Model-based dispersive processing of borehole dipole wave data using an equivalent-tool theory: Geophysics, 81, no. 1, D35–D43, doi: 10.1190/geo2015-0210.1.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Lee, X. Q., H. Chen, X. He, X. M. Wang, and J. S. Cong, 2013, Analyses on mode waves of acoustic logging while drilling in transversely isotropic formations: Chinese Journal of Geophysics, 56, 3212–3222, doi: 10.6038/cjg20130933.
    Google Scholar
  • Schmitt, D. P., 1989, Acoustic multipole logging in transversely isotropic poroelastic formations: The Journal of Acoustical Society of America, 86, 2397–2421, doi: 10.1121/1.398448.
    Web of ScienceGoogle Scholar
  • Schoenberg, M., F. Muir, and C. M. Sayers, 1996, Introducing ANNIE: A simple three-parameter anisotropic velocity model for shales: Journal of Seismic Exploration, 5, 35–49.
    Web of ScienceGoogle Scholar
  • Sinha, B. K., and E. Simsek, 2010, Sonic logging in deviated wellbores in the presence of a drill collar: 80th Annual International Meeting, SEG, Expanded Abstracts, 553–557, doi: 10.1190/1.3513843.
    Google Scholar
  • Sinha, B. K., E. Simsek, and S. Asvadurov, 2009, Influence of a pipe tool on borehole modes: Geophysics, 74, no. 3, E111–E123, doi: 10.1190/1.3085644.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Su, Y. D., C. Jiang, C. X. Zhuang, S. Xu, and X. M. Tang, 2016, Joint inversion of logging-while-drilling multipole acoustic data to determine P- and S-wave velocities in unconsolidated slow formations: Geophysics, 81, no. 5, D553–D560, doi: 10.1190/geo2016-0133.1.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Tang, X. M., 2003, Determining formation shear-wave transverse isotropy from borehole Stoneley-wave measurements: Geophysics, 68, 118–126, doi: 10.1190/1.1543199.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Tang, X. M., and C. H. Cheng, 2004, Quantitative borehole acoustic methods: Elsevier Science Publishing Company Inc.
    Google Scholar
  • Tang, X. M., V. Dubinsky, and D. J. Patterson, 2006, Development of a low-frequency LWD quadrupole shear-wave technology to improve quality of formation shear velocity measurement: Annual Technical Conference and Exhibition, SPE, Extended Abstracts, doi: 10.2118/102335-MS.
    Google Scholar
  • Tang, X. M., V. Dubinsky, T. Wang, A. Bolshakov, and D. Patterson, 2003, Shear-velocity measurement in the logging-while-drilling environment: Modeling and field evaluations: Petrophysics, 44, 79–90.
    Google Scholar
  • Tang, X. M., and D. J. Patterson, 2010, Mapping formation radial shear-wave velocity variation by a constrained inversion of borehole flexural-wave dispersion data: Geophysics, 75, no. 6, E183–E190, doi: 10.1190/1.3502664.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Thomsen, L., 1986, Weak elastic anisotropy: Geophysics, 51, 1954–1966, doi: 10.1190/1.1442051.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Wang, H., and G. Tao, 2011, Wave field simulation and data acquisition scheme analysis for LWD acoustic tools in very slow formations: Geophysics, 76, no. 3, E59–E68, doi: 10.1190/1.3552929.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Wang, R. J., and W. X. Qiao, 2015, Numerical study on quadrupole acoustic LWD in VTI formations: Chinese Journal of Geophysics, 58, 2862–2872, doi: 10.6038/cjg20150820.
    Google Scholar
  • Wei, J. Q., X. He, H. Chen, and X. M. Wang, 2018, Inversion of anisotropy in a TTI stratum using quadrupole acoustic LWD and multimode acquisition: Chinese Journal of Geophysics, 61, 792–802, doi: 10.6038/cjg2018L0410.
    Google Scholar
  • White, J. E., and C. Tongtaow, 1981, Cylindrical waves in transversely isotropic media: The Journal of Acoustical Society of America, 70, 1147–1155, doi: 10.1121/1.386946.
    Web of ScienceGoogle Scholar
  • Xu, S., X. M. Tang, Y. D. Su, S. Q. Lee, and C. X. Zhuang, 2017, Determining formation S-wave transverse isotropy from borehole flexural-wave dispersion data: Geophysics, 82, no. 2, D47–D55, doi: 10.1190/geo2016-0223.1.GPYSA70016-8033
    Web of ScienceGoogle Scholar
  • Xu, S., X. M. Tang, Y. D. Su, and C. X. Zhuang, 2018c, Determining formation shear wave transverse isotropy jointly from borehole Stoneley- and flexural-wave data: Chinese Journal of Geophysics, 61, 5105–5114, doi: 10.6038/cjg2018L0521.
    Google Scholar
  • Xu, S., X. M. Tang, C. Torres-Verdín, and Y. D. Su, 2018a, Seismic shear wave anisotropy in cracked rocks and an application to hydraulic fracturing: Geophysical Research Letters, 45, 5390–5397, doi: 10.1029/2018GL077931.GPRLAJ0094-8276
    Web of ScienceGoogle Scholar
  • Xu, S., C. X. Zhuang, Y. D. Su, Y. K. Liu, Z. P. Zhang, S. J. Guo, and X. M. Tang, 2018b, Acoustic source characterization for a logging while drilling tool: Theoretical and experimental modeling: The Journal of the Acoustical Society of America, 144, EL178–EL184, doi: 10.1121/1.5053105.
    Web of ScienceGoogle Scholar