Abstract
The Geodetic-Geodynamic network (G1) was established with the intention of monitoring recent crustal deformations in Israel and serving as a major control network. In 1996 the network was measured for the first time using GPS. The goal of the proposed design is to improve the ability of the network to detect and measure movements and deformations, based on the geological phenomena to be monitored, while satisfying the demand for high accuracy and reliability. This paper presents the network configuration design of the second GPS measurement campaign of the G1 network held during 2002. Sensitivity analysis of the network, as dependent upon a postulated velocity field, was used as the basis for the network configuration design.
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9 References
Baarda, W. (1968). A Testing Procedure for Use in Geodetic Networks. Netherlands Geodetic Commission, Publications on Geodesy, New Series 2, No. 5.
Cooper, M. A. R. (1987). Control Surveys in Civil Engineering. Collins, London.
Even-Tzur, G. (2002). “GPS Vector Configuration Design for Monitoring Deformation Networks.” Journal of Geodesy, 76(8), 455–461.
Even-Tzur G. (2001). “Sensitivity Analysis of Monitoring Deformation Networks in The North of Israel.” Israel Journal of Earth Sciences, 50(1): 23–27.
Even-Tzur, G. (1999). “Sensitivity Design for Monitoring Deformation Networks.” Bollettino Di Geodesia E Scienze Affini,. 58(4): 314–324.
Karcz, I. (1994). “Geological Considerations in Design of the Seminal Dead Sea Rift Network.” Perelmuter Workshop on Dynamic Deformation Models, Haifa, Israel.
Ostrovsky, E. (2001). “The G1 GPS Geodetic-Geodynamic Reference Network: Final Processing Results.” Israel Journal of Earth Science,. 50(1): 29–37.
Pe’eri, S., Wdowinski, S., Shtibelman, A. and Bechor, N. (2002). “Current Plate Motion Across the Dead Sea Fault from Three Years of Continues GPS Monitoring.” Geophysical Research Letters,. 29(14): 42-1–42-4.
Rao C. R., Mitra S. K. (1971). Generalized Inverse of Matrices and its Application. John Wiley and Sons, New York.
Rothacher, M. and L. Mervart (Eds.) (1996). Bernese GPS Software. Ver. 4.0. Astronomical Institute, University of Berne.
Wdowinski, S., Y. Bock, G. Baer, L. Prawirodirdjo, N. Bechor, S. Naaman, R. Knafo, Y. Forrai and Y. Melzer (2004). “GPS measurements of current crustal movements along the Dead Sea Fault.” J. Geophys. Res., 109(B5)
Weertman, J. and Weertman, J.R. (1964). Elementary Dislocation Theory. Macmillan, New-York.
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© 2006 Springer-Verlag Berlin Heidelberg
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Even-Tzur, G. (2006). Designing the Configuration of the Geodetic-Geodynamic Network in Israel. In: Sansò, F., Gil, A.J. (eds) Geodetic Deformation Monitoring: From Geophysical to Engineering Roles. International Association of Geodesy Symposia, vol 131. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-38596-7_17
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DOI: https://doi.org/10.1007/978-3-540-38596-7_17
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-540-38595-0
Online ISBN: 978-3-540-38596-7
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