Your browser does not support JavaScript!
http://iet.metastore.ingenta.com
1887

Detection of events in seismic time series by time–frequency methods

Detection of events in seismic time series by time–frequency methods

For access to this article, please select a purchase option:

Buy article PDF
£12.50
(plus tax if applicable)
Add to cart
Buy Knowledge Pack
10 articles for £75.00
(plus taxes if applicable)
Add to cart

IET members benefit from discounts to all IET publications and free access to E&T Magazine. If you are an IET member, log in to your account and the discounts will automatically be applied.

Learn more about IET membership 

Recommend Title Publication to library

You must fill out fields marked with: *

Librarian details
Name:*
Email:*
Your details
Name:*
Email:*
Department:*
Why are you recommending this title?
Select reason:
 
 
 
 
 
IET Signal Processing — Recommend this title to your library

Thank you

Your recommendation has been sent to your librarian.

© The Institution of Engineering and Technology
Published

The detection of events in seismic time series has been a subject of great interest during the last 30 years. Most of the works in this area were based on detecting special patterns or clusters in seismic data. The authors present here a event detection method based on a time–frequency analysis through the Wigner distribution (WD). The proposed method consists on defining an appropriate entropic measure through a suitable time–frequency distribution, acting as probability distribution function. It is known from previous studies in the field that the information entailed by time–frequency representations (TFR) of time signals can be explored by means of different Rényi entropy measures. The non-positivity character of the WD implies that the classical Shannon entropy cannot be used, and therefore it has been replaced by a generalised measure such as the Rényi entropy. However, owing to the existence of multiple TFR normalisations, the so-called quantum normalisation has been empirically selected here for this particular application. This method is based on the identification of the events as those temporal clusters having the highest amount of information (entropy). The method is described and applied to different earthquake signals and volcanic tremors, using both real and synthetic data. The results are compared to other existing event detection methods.

Inspec keywords: geophysical signal processing; seismology; geophysical techniques; earthquakes; time-frequency analysis

Other keywords: volcanic tremors; seismic time series; earthquake signals; Renyi entropy measures; classical Shannon entropy; probability distribution function; Wigner distribution; quantum normalisation; time-frequency representations; time-frequency methods; event detection method

Subjects: Geophysical techniques and equipment; Seismic sources; Signal processing and detection; Data and information; acquisition, processing, storage and dissemination in geophysics; Instrumentation and techniques for geophysical, hydrospheric and lower atmosphere research

References

    1. 1)
      • Pitton, J., Loughlin, P., Atlas, L.: `Positive time-frequency distributions via maximum entropy deconvolution of the evolutionary spectrum', Proc. ICASSP, 1993, IV, p. 436–439.
    2. 2)
      • C. Shannon , W. Weaver . (1949) The mathematical theory of communication.
    3. 3)
      • A. Yadollahi , Z. Moussavi , M.B. Shamsollahi1 , Z. Ahmadinejad . Heart sounds localization using lung sounds entropy. Int. J. Sci. Res. , 107 - 111
    4. 4)
      • R. Zou , W.A. Cupples , K.P. Yip , N.H. Holstein-Rathlou , K.H. Chon . Time-varying properties of renal autoregulatory mechanisms. IEEE Trans. Biomed. Engng. , 10 , 1112 - 1120
    5. 5)
      • L. Stanković . A method for time–frequency analysis. IEEE Trans. Signal Process. , 225 - 229
    6. 6)
      • G.J. van den Hazel . Seismic event detection using arrays – a comparison of 2 approaches.
    7. 7)
      • Köhler, A., Ohrnberger, M., Riggelsen, C., Scherbaum, F.: `Unsupervised feature selection for pattern search in seismic time series', JMLR: Workshop and Conf. Proc., 2008, 4, p. 106–121.
    8. 8)
      • E.P. Wigner . On the quantum correction for thermodynamic equilibrium. Phys. Rev. , 749 - 759
    9. 9)
      • A.T. Walden . Spatial clustering: using simple summaries of seismic data to find the edge of an oil-field. Appl. Stat. , 385 - 398
    10. 10)
      • H.C. Hagen . The application of principal components analysis to seismic datasets. Geoexploration , 93 - 111
    11. 11)
      • L. Stankovic . A measure of some time–frequency distributions concentration. Signal Process. , 621 - 631
    12. 12)
      • A. Rényi , P. Turán . (1976) Some fundamental questions of information theory, Selected Papers of Alfréd Rényi.
    13. 13)
      • K.H. Brenner . A discrete version of the Wigner distribution function. Proc. EURASIP Signal Process. II: Theories Appl. , 307 - 309
    14. 14)
      • P. Bois . Autoregressive pattern recognition applied to the delimitation of oil and gas reservoirs. Geophys. Prosp. , 572 - 591
    15. 15)
      • Gabarda, S., Cristóbal, G., Martínez-Alajarín, J., Ruiz, R.: `Detection of events in biomedical signals by a Rényi entropy measure', Information Optics: 5th Int. Workshop on Information Optics (WIO'06). AIP Conf. Proc., 2006, 860, p. 210–219.
    16. 16)
      • Sang, T.H., Williams, W.J.: `Rényi information and signal dependent optimal kernel design', Proc. ICASSP, 1995, 2, p. 997–1000.
    17. 17)
      • J. Dumay , F. Fournier . Multivariate statistical analyses applied to seismic facies recognition. Geophysics , 1151 - 59
    18. 18)
      • T.E. Endo , T. Murray . Real-time seismic amplitude measurement (RSAM): a volcano monitoring and prediction tool. Bull. Volcanol. , 533 - 545
    19. 19)
      • R. Eisberg , R. Resnick . (1974) Quantum physics.
    20. 20)
      • T.A.C.M. Claasen , W.F.G. Mecklenbräuker . The Wigner distribution – a tool for time frequency analysis. Philips J. Res. Parts I–III , 217 - 250
    21. 21)
      • D. Vakman . Optimum signals which minimize partial volume under an ambiguity surface. Radio Engng. Electron. Phys. , 1260 - 1268
    22. 22)
      • H.J. Grubb , A.T. Walden . Characterizing seismic time series using the discrete wavelet transform. Geophys. Prosp. , 183 - 205
    23. 23)
      • W.J. Williams , M.L. Brown , A.O. Hero . Uncertainty, information and time–frequency distributions. SPIE Adv. Signal Process , 144 - 156
    24. 24)
      • T. Bartosch , D. Seidl . Spectrogram analysis of selected tremor signals using short-time Fourier transform and continuous wavelet transform. Ann. Geophys , 497 - 506
    25. 25)
      • Flandrin, P., Baraniuk, R.G., Michel, O.: `Time–frequency complexity and information', Proc. ICASSP, 1994, 3, p. 329–332.
    26. 26)
      • A. Plešinger , P. Kolár . Interactive demonstration of the effect of causal and acausal frequency filtering on seismic signals.
    27. 27)
      • L.D. Jacobson , H. Wechsler . Joint spatial/spatial-frequency representation. Signal Process. , 37 - 68
    28. 28)
      • V. Lendzionowski , A.T. Walden , R.E. White . Seismic character mapping over reservoir intervals. Geophys. Prosp. , 951 - 969
    29. 29)
      • L. Cohen . Generalized phase-space distribution functions. J. Math. Phys. , 781 - 786
    30. 30)
      • B. Melton , L. Bailey . Multiple signal correlators. Geophysics , 3 , 565 - 588
http://iet.metastore.ingenta.com/content/journals/10.1049/iet-spr.2009.0125
Loading

Related content

content/journals/10.1049/iet-spr.2009.0125
pub_keyword,iet_inspecKeyword,pub_concept
6
6
Loading
Print this page
This is a required field
Please enter a valid email address