Evaluation of the displacements of the permanent GPS stations of Beni Haroun Dam geodetic network (Algeria)

• Autorzy: Khelifa Sofane , Dekkiche Hicham , Kahlouche Salem , Boudina Samia

Identyfikatory

DOI

10.1007/s11600-021-00689-0

• Języki publikacji: EN

Abstrakty

EN

The purpose of this paper is the analysis of the daily coordinate time series of the five permanent GPS (Global Positioning System) stations of the geodetic monitoring network of the Beni-Haroun Dam (Algeria), in order to assess the spectral content of the dam displacements. The coordinate time series analysis was based on the singular spectrum analysis to assess their principal components (trend, seasonal components and noise in phase space), the spectral analysis to identify their noise spectrum (white or colored) and the wavelet thresholding method to determine their noise in frequency space. The results showed that the primary signal present in the analyzed time series is mainly composed of a trend and an annual component. The trend and the annual signal explain more than 95% of the total signal in the three coordinates (x, y, z) for all studied stations. The analyzed time series in the three coordinates (x, y, z) are characterized by a linear drift less than 1 mm/year, their annual amplitudes are in the range of 0.5–2 mm, and the amplitudes of their semiannual, four-monthly and quarterly signals are in the range of 0–0.5 mm. The noise spectrum in the analyzed time series is flicker noise, and the noise level is in the range of 0.2–0.7 mm, 0.3–0.5 mm and 0.5–1.2 mm in, respectively, x-, y- and z-coordinates. The low values of trend and noise level in the analyzed station coordinates indicate that the Beni-Haroun Dam is qualified as stable.

Słowa kluczowe

EN

geodetic monitoring; Beni-Haroun dam; time series analysis; GPS dam auscultation

PL

monitoring geodezyjny; zapora Beni-Haroun; analiza szeregów czasowych

• Wydawca: Instytut Geofizyki PAN ; Springer
• Czasopismo: Acta Geophysica
• Rocznik: 2021
• Tom: Vol. 69, no. 6
• Strony: 2129--2143
• Opis fizyczny: Bibliogr. 30 poz.

Twórcy

autor

Khelifa Sofane

• Centre des Techniques Spatiales, Agence Spatiale Algérienne, PO Box13, Arzew, Algeria

• https://orcid.org/0000-0003-4772-1270

autor

Dekkiche Hicham

• Centre des Techniques Spatiales, Agence Spatiale Algérienne, PO Box13, Arzew, Algeria

autor

Kahlouche Salem

• Centre des Techniques Spatiales, Agence Spatiale Algérienne, PO Box13, Arzew, Algeria

autor

Boudina Samia

• Agence Nationale des Barrages et Transferts, PO Box 235, Kouba (Alger), Algeria

Bibliografia

• 1. Acosta L, De Lacy M, Ramos M, Cano J, Herrera A, Avilés M, Gil A (2018) Displacements study of an earth fill dam based on high precision geodetic monitoring and numerical modeling. Sensors 18(5):1369
• 2. Agnew DC (1992) The time-domain behaviour of power-law noises. Geophys Res Lett 19(4):333–336
• 3. Alcay S, Yigit CO, Inal C, Ceylan A (2018) Analysis of Displacement response of the Ermenek dam monitored by an integrated geodetic and pendulum system. Int J Civ Eng 16:1279–1291
• 4. Allan DW (1987) Time and frequency characterisation, estimation and prediction of precision clocks and oscillators. IEEE Trans UFFC 34:647–654
• 5. Barzaghi R, Cazzaniga NE, De Gaetani CI, Pinto L, Tornatore V (2018) Estimating and comparing dam deformation using classical and GNSS techniques. Sensors 18(3):756
• 6. Bouin MN (2010) Méthodologie GPS, mesure des déformations verticales et humidité atmosphérique. Université de Bretagne Occidentale, France, Mémoire d’habilitation à diriger les recherches
• 7. Broomhead DS, King GP (1986) Extracting qualitative dynamics from experimental data. Phys D 20:217–236
• 8. Daubechies I (1992) Ten lectures on wavelets. Society for industrial and applied mathematics, United States
• 9. Donoho D (1995) Denoising by soft-thresholding. IEEE T Inform Theory 41(3):613–627
• 10. Donoho D, Johnstone I (1994) Ideal spatial adaptation via wavelet shrinkage. Biometrika 81:425–455
• 11. Feissel-Vernier M, de Viron O, Le Bail K (2007) Stability of VLBI, SLR, DORIS, and GPS positioning. Earth Planets Space 59:475–497
• 12. Genrich JF, Boch Y (1992) Rapid resolution of crustal motion at short ranges with the global positioning system. J Geophys Res 97(B3):3261–3269
• 13. Ghil M, Allen MR, Dettinger MD, Ide K, Kondrashov D, Mann ME, Robertson AW, Saunders A, Tian Y, Varadi F, Yiou P (2002) Advanced spectral methods for climatic time series. Rev Geophys 40(1):3-1-3–41
• 14. Guler G, Kilic H, Hosbas G, Ozaydın K (2006) Evaluation of the movements of the dam embankments by means of geodetic and geotechnical methods. J Surv Eng 132:31–39
• 15. Johnstone I, Silverman BW (1997) Wavelet threshold estimators for data with correlated noise. J Roy Statist Soc B 59:319–351
• 16. Kalkan Y (2014) Geodetic deformation monitoring of Ataturk Dam in Turkey. Arab J Geosci 7(1):397–405
• 17. Khelifa S, Kahlouche S, Belbachir MF (2013) Analysis of position time series of GPS-DORIS co-located stations. Int J Appl Earth Obs Geoinf 20:67–76
• 18. Khelifa S (2016) Noise in DORIS station position time series provided by IGN-JPL, INASAN and CNES-CLS analysis centres for the ITRF2014 realization. Adv Space Res 58(12):2572–2588
• 19. Khelifa S, Gourine B, Taibi H (2018) Dekkiche H (2018) Filling gaps in time series of space-geodetic positioning. Arab J Geosci 11:329
• 20. Konakoglu B, Cakir L, Yilmaz V (2020) Monitoring the deformation of a concrete dam: a case study on the Deriner Dam, Artvin, Turkey. Geomat Nat Haz Risk 11(1):160–177
• 21. Le Bail K (2006) Estimating the noise in space-geodetic positioning: the case of DORIS. J Geod 80(8–11):541–565
• 22. Mallat S (1999) A wavelet tour of signal processing. Academic Press, United States
• 23. Mao A, Harrison CGA, Dixon TH (1999) Noise in GPS coordinate time series. J Geophys Res 104(B2):2797–2816
• 24. Pytharouli SI, Stiros CS (2005) Deformation and reservoir level fluctuations: evidence for a causative relationship from spectral analysis of a geodetic monitoring record. Eng Struct 27:361–370
• 25. Sedlak V, Jecny M (2004) Deformation measurements on bulk dam of waterwork in East Slovakia. Geol Ecol Min Serv L(2):1–10
• 26. Taşçi L (2008) Dam deformation measurements with GPS. Geod Cartogr 34(4):116–121
• 27. Vautard R, Ghil M (1989) Singular spectrum analysis in nonlinear dynamics, with applications to paleoclimatic time series. Physica D 35:395–424
• 28. Wang GQ (2012) Kinematics of the Cerca del Cielo, Puerto Rico landslide derived from GPS observations. Landslides 9(1):117–130
• 29. Welch P (1967) The use of Fast Fourier Transform for the estimation of power spectra: A method based on time averaging over short, modified periodograms. IEEE Trans Audio Electroacoust 15(2):70–73
• 30. Yigit CO, Alcay S, Ceylan A (2016) Displacement response of a concrete arch dam to seasonal temperature fluctuations and reservoir level rise during the first filling period: evidence from geodetic data. Geomat Nat Haz Risk 7(4):1489–1505