A satellite-based digital data system for low-frequency geophysical data

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A satellite-based digital data system for low-frequency geophysical data

STAN SILVERMAN, CARL MORTENSEN and MALCOLM JOHNSTON

U.S. GEOLOGICAL SURVEY MS/977, 345 MIDDLEFIELD ROAD, MENLO PARK, CALIFORNIA 94025

Abstract

A reliable method for collection, display, and analysis of low-frequencygeophysical data from isolated sites, which can be throughoutNorth and South America and the Pacific Rim, has been developedfor use with the Geostationary Operational Environmental Satellite(GOES) system. Geophysical data primarily intended for earthquakehazard and crustal deformation monitoring are digitized witheither 12-bit or 16-bit resolution and transmitted every 10min through a satellite link to a bank of UNIX-based computersin Menlo Park, California. There the data are available foranalysis and display within a few seconds of their transmittime. This system provides real-time monitoring of crustal deformationparameters such as tilt, strain, fault displacement, local magneticfield, crustal geochemistry, and water levels, as well as meteorologicaland other parameters, along faults in California and Alaska,and in volcanic regions in the western United States, Rabaul,and other locations in the New Britain region of the South Pacific.Various mathematical, statistical, and graphical algorithmsprocess the incoming data to detect changes in crustal deformationand fault slip that may indicate the first stages of catastrophicfault failure. Alert trigger levels based on physical models,signal resolution, and previous history have been defined forparticular instrument types. Computer-driven remote paging andmail systems are used to notify appropriate personnel when alarmstatus is reached. The system supports continuous historicalrecords of low-frequency geophysical data, software for extensiveanalysis of these data, and programs for modeling fault rupturewith and without seismic radiation, as well as providing anenvironment for real-time attempts at earthquake prediction.

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