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THE INTERPRETATION OF TRAVELTIME FIELDS IN REFRACTION SEISMOLOGY (1987)

BRÜCKL, E.

Oxford, UK : Blackwell Publishing Ltd

Geophysical prospecting 35 (1987), S. 0

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ISSN: 1365-2478

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Geosciences , Physics

Notes: We consider multiply covered traveltimes of first or later arrivals which are gathered along a refraction seismic profile. The two-dimensional distribution of these traveltimes above a coordinate frame generated by the shotpoint axis and the geophone axis or by the common midpoint axis and the offset axis is named a traveltime field.The application of the principle of reciprocity to the traveltime field implies that for each traveltime value with a negative offset there is a corresponding equal value with positive offset. In appendix A procedures are demonstrated which minimize the observational errors of traveltimes inherent in particular traveltime branches or complete common shotpoint sections.The application of the principle of parallelism to an area of the traveltime field associated with a particular refractor can be formulated as a partial differential equation corresponding to the type of the vibrating string. The solution of this equation signifies that the two-dimensional distribution of these traveltimes may be generated by the sum of two one-dimensional functions which depend on the shotpoint coordinate and the geophone coordinate. Physically, these two functions may be interpreted as the mean traveltime branches of the reverse and the normal shot. In appendix B procedures are described which compute these two functions from real traveltime observations by a least-squares fit.The application of these regressed traveltime field data to known time-to-depth conversion methods is straightforward and more accurate and flexible than the use of individual traveltime branches. The wavefront method, the plus-minus method, the generalized reciprocal method and a ray tracing method are considered in detail. A field example demonstrates the adjustment of regressed traveltime fields to observed traveltime data. A time-to-depth conversion is also demonstrated applying a ray tracing method.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1365-2478.1987.tb00855.x

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Graphical Location of Seismic Sources Based on Amplitude Ratios (2018)

Brückl E.

Seismological Society of America (SSA)

In: Seismological Research Letters

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Publication Date: 2018

Description: 〈span〉〈div〉ABSTRACT〈/div〉Methods for location of seismic sources based on amplitudes provide an alternative to standard methods in cases with high ambient noise and emergent, multiple event, or tremor‐type source functions. Numerical methods using amplitudes or amplitude ratios have been described and successfully applied in several previous studies. In this article, a graphical location method based on amplitude ratios is presented, which may be of interest to students and others who want to learn about seismology due of its computational simplicity and the clarity of the solution.The most basic empirical relation to model the decay of the seismic amplitude maxima with distance is a power law. Given this relation, the ratio of the distances of two seismic stations to the seismic source is uniquely determined by the ratio of the amplitudes recorded at these stations. The geometrical loci of all points with a constant distance ratio is in what is known as an “Apollonius circle” in 2D, and in a sphere with the center and radius of the Apollonius circle in 3D. The graphical location method presented in this article considers the circular intersections of these spheres with a horizontal plane, preferentially in the level of the source location. Data from a low‐cost seismic sensor network in the southern Vienna basin are used to demonstrate the potential application of the method.〈/span〉

Print ISSN: 0895-0695

Electronic ISSN: 1938-2057

Topics: Geosciences