Seismic Surveillance. Nuclear Test Ban Verification

The research can be divided into three main topics: (1) robust seismic event location schemes; (2) crustal structure mapping; and (3) teleseismic P- coda scattering analysis. New techniques are presented for fast and robust event location. In case of available arrival times from a network of seismog...

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Bibliographic Details
Main Authors: Husebye, Eystein S., Ruud, Bent O.
Other Authors: OSLO UNIV (NORWAY) DEPT OF GEOLOGY
Format: Text
Language:English
Published: 1990
Subjects:
Seismic Detection and Detectors
*SEISMIC SIGNATURES
*NUCLEAR EXPLOSION DETECTION
SPHERES
LONG RANGE(DISTANCE)
ERRORS
EARTH CRUST
SEISMIC WAVES
PARTS
MAPPING
HYPOTHESES
RANGE(DISTANCE)
ARRIVAL
AZIMUTH
SURVEILLANCE
SEISMOLOGY
TRAVEL TIME
FITTINGS
SEISMOGRAPHS
NORTHERN EUROPE
NETWORKS
STRUCTURES
NORESS SEISMIC ARRAY
ARCESS SEISMIC ARRAY
FINESA SEISMIC ARRAY
SEISMIC DISCRIMINATION
PE61101E
WUGL9A10DAAE
Fennoscandia
Online Access:http://www.dtic.mil/docs/citations/ADA221768
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA221768
Description
Summary:The research can be divided into three main topics: (1) robust seismic event location schemes; (2) crustal structure mapping; and (3) teleseismic P- coda scattering analysis. New techniques are presented for fast and robust event location. In case of available arrival times from a network of seismograph network (aperture up to 10-15 deg) a variant of Geiger's method for fitting arrival times to travel time tables, gave average location errors less than 1 deg in the teleseismic distance range. In another study, the location schemes are tied to the slowness vector as easily derived from arrays and 3-component stations, namely azimuth error minimization and slowness vector summation on a sphere for N arbitrary positioned stations. Crustal structures are managed for various parts of Fennoscandia where the 3 seismic arrays NORESS, ARCESS and FINESA are sited. NORESS P-wave coda of 75 s duration from 8 teleseismic events of widely different azimuths have been examined using both array and 3C analysis techniques. Although source-end scattering could not be separated from the source pulse per se, favor the hypothesis of long source duration is supported by observed slow beam amplitude decay rates. The majority of receiver-end scattering contributions appears to be P-to-Rg conversions in both forward and backward modes from two nearby areas with pronounced/topographic reliefs. (JHD)

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