Statistical Analysis of the Temporal Pattern of Seismicity in the Zagros Region

Document Type : Articles

Authors

1 School of Earth Sciences, Damghan University, Damghan, Iran

2 School of Mathematics and Computer Science, Damghan University, Damghan, Iran

Abstract

Introduction: Earthquake is one of the major natural disasters that the current knowledge of the human kind is not able to predict it yet; however, it can be partly subjected to risk assessment and recognition of its pattern by using statistical methods. The Zagros region of Iran is known for its high seismic activity. This mountain belt is amongst the world’s most seismically active mountain ranges. This seismogenic zone is the result of the collision between the Arabian and Eurasian plates during the Cenozoic. Seismic activity in this zone is characterized by the occurrence of low to moderate magnitude earthquakes, most of which nucleate on blind (hidden) thrust faults. In this study,the temporal patternof occurrence of earthquakes in the Zagros region for a period of more than 11years,from the beginning of 2005to the end of October 2016, have been examined using statistical methods.In this regard, thematching degree of the examineddata withthe Poisson distributionwas evaluated and time seriesanalysis of the data was carried out.Methodology and Data Analysis: Randomness in time, space and size is the most obvious property of earthquake occurrence. At the same time, there are ample evidences to suggest that earthquakes do not occur in a completely disordered manner. The randomness of the occurrence of earthquakes in time or space can be evaluated by statistical methods such as Poisson distribution fitting test. In addition, time series analysis has been widely used in many applications, e.g. earthquake forecasting and the temporal pattern of earthquake occurrences, as a stochastic process, can be studied by this method. In this study, by using the goodness of fit test based on the chi-square statistic, the suitability of the Poisson distribution with λ parameter (the average rate of the earthquake occurrence) fitness to seismic data of the region with different ranges was assessed. Additionally, in this research, due to the low randomness degree of the data in time, the time series modeling of the data were carried out to find theproductive time patternmodel of the data.A sample of 150 data, covering the end part of the catalogue, was selected for the analysis and modeling of time series, andtwo main attributes of the earthquake data, magnitude and focal depth,as quantitative variables, were included in this modeling. Results and Discussion: According to the obtained results, it can be said that temporal distribution of these data do not completely follow the Poisson distribution model, but with increasing the earthquake magnitude, the data probability distribution approaches to the Poisson distribution. Besides, the results of the time series analysis of data showthatthe temporal pattern of earthquake occurrence based on the magnitudevariablehas a good correlation with ARMA(1,1) model. Similarly, considering the focal depth as variable in modeling, the time series models acceptably match ARMA(0,1) andARMA(0,2) models. These findings were verified by Box and Pierce method. According to the obtained results of this research, it is concluded that the earthquake occurrence in the Zagros region do not completely show a random pattern, and time series analysis modeling can be acceptably employed for finding the temporal behavior of seismicity in this region. However, the techniques used in this research are data driven and the reliability of the results obtained depends on the quality of the input datasets. Due to the insufficiency and inaccuracy of the studied data catalogue, it is expected that in future,more appropriateand reliable results could be achieved by reducing the seismic data errors and using the data with longer time periods.

Keywords

References

  1. Altinok, Y. and Kolcak, D. (1999) An application of the semi-Markov model for earthquake occurrences in North Anatolia, Turkey. Journal of Balkan Geophysical Society, 2(4), 90-99.
  2. Morales-Esteban, A., Martinez- Alvarez, F., Troncoso, A., Justo, J.L., and Rubio-Escudero, C. (2010) Pattern recognition to forecast seismic time series. Expert Systems with Application, 37(12), 8333-8342.
  3. Wang, J.P., Huang, D., Chang, S.C., and Wu, Y.M. (2014) New evidence and perspective to the Poisson process and earthquake temporal distribution from 55,000 events around Taiwan since 1900. Natural Hazards Review, 15(1), 38- 47.
  4. Bossard, A. (2014) Analysis of the Poisson distribution applicability to the Japanese seismic activity. International Conference on Advanced Applied Informatics, 93, 430- 435.
  5. Wang, J.P. and Chin Chang, S.U. (2015) Evidence in support of seismic hazard following Poisson distribution. Physica A, 424, 207-216.
  6. Zamani, A. and Agh-Atabai, M. (2009) Temporal characteristics of seismicity in the Alborz and Zagros regions of Iran, using a multifractal approach. Journal of Geodynamics, 47(5), 271-279.
  7. Pashapoor, M., Khorshidian, K., and Khalili, M. (2014) The parametric estimation and prediction of earthquake occurrences in the south of Iran based on a semi-Markov model. Journal of Advanced Mathematical modeling, 3(2), 1-20 [in Persian].
  8. Mohebbi, M. and Abedini, Y. (2006) Analysis of the earthquake data using time series and prediction methods. Iranian National Conference on Physics, Shahrud University of Technology, Shahrud, Iran [in Persian].
  9. Zuniga, F.R., Reyners, M., and Villamor, P. (2005) Temporal variations of the earthquake data in the catalogue of seismicity of New Zealand. Bulletin of the New Zealand Society for Earthquake Engineering, 38(2), 87-105.
  10. Amei, A., Fu, W., and Ho, C. (2012) Time series analysis for predicting the occurrences of large scale earthquakes. International Journal of Applied Science and Technology, 2(7), 64-75.
  11. Hong, L.L. and Guo, S.W. (1995) Nonstationary Poisson Model for Earthquake Occurrences. Bulletin of the Seismological Society of America, 85, 814-824.
  12. Telesca, L., Cuomo, V., Lapenna, V., and Macchiato, M. (2001) Identifying space time clustering properties of the 1983-1997 Irpinia-Basilicata (southern Italy) seismicity. Tectonophysics, 330, 93-102.
  13. Berberian, M. (1981) 'Active faulting and tectonics of Iran'. In: Zagros Hindukush-Himalaya Geodynamic Evolution. Geodynamics Series, 3, Gupta, H.K., Delany, F.M. (Eds) American
  14. Geophysical Union Washington, DC and Geological Society of America, Boulder, CO, 33-69.
  15. Takin, M. (1972) Iranian geology and continental drift in the Middle East. Nature, 235, 147-150.
  16. Falcon, N.L. (1969) 'Problems of the relationship between surface structure and deep displacements illustrated by the Zagros Range'. In: Time and Place in Orogeny, Kent, P.E., Satterthwaite, G.E. and Spencer, A.M. (Eds), 3, Geol. Soc. Lonon, Spec. Publ., 9-22.
  17. Swan, A.R.H. and Sandilands, M.H. (1995) Introduction to Geological Data Analysis. Blackwell Science, Oxford.
  18. Schuenemeyer, J.H. and Drew, L.J. (2011) Statistics for Earth and Environmental Scientists. John Willy & Sons, Inc., Hoboken.
  19. Kagan, Y.Y. (1993) Statistics of Characteristic Earthquakes. Bulletin of the Seismological Society of America, 83, 7-24.
  20. Kagan, Y.Y. (2010) Statistical distribution of earthquake numbers: consequence of branching process. Geophysical Journal International, 180Â‌ (3), 1313-1328.
  21. Armstrong, J.S. (2001) Principles of Forecasting: A Handbook for Researchers and Practitioners. Kluwer Academic Publishers, Norwell, MA.
  22. Box, G.E.P. and Jenkins, G.M. (1976) Time Series Analysis: Forecasting and Control. Holden-Day, San Francisco.
  23. Brockwell, P.J. and Davis, R.A. (2002) Introduction to Time Series and Forecasting. 2nd Edition. Springer-Verlag, New York.
  24. Hessami, Kh., Jamali, F., and Tabassi, H. (2003) Map of Major Faults of Iran, scale; 1:2,500,000. International Institute of Earthquake Engineering and Seismology, Tehran, Iran [in Persian].

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History

  • Receive Date: 09 September 2016
  • Revise Date: 24 February 2021
  • Accept Date: 26 December 2020

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