Abstract
The detection and location capability of the International Monitoring System for small seismic events in the continental and oceanic regions surrounding the Sea of Japan is determined mainly by three primary seismic arrays: USRK, KSRS, and MJAR. Body wave arrivals are coherent on USRK and KSRS up to frequencies of around 4 Hz and classical array processing methods can detect and extract features for most regional signals on these stations. We demonstrate how empirical matched field processing (EMFP), a generalization of frequency-wavenumber or f-k analysis, can contribute to calibrated direction estimates which mitigate bias resulting from near-station geological structure. It does this by comparing the narrowband phase shifts between the signals on different sensors, observed at a given time, with corresponding measurements on signals from historical seismic events. The EMFP detection statistic is usually evaluated as a function of source location rather than slowness space and the size of the geographical footprint valid for EMFP templates is affected by array geometry, the availablesignal bandwidth, and Earth structure over the propagation path. The MJAR arrayhas similar dimensions to KSRS but is sited in far more complex geology which results in poor parameter estimates with classical f-k analysis for all signals lacking energy at 1 Hz or below. EMFP mitigates the signal incoherence to some degree but the geographical footprint valid for a given matched field template on MJAR is very small. Spectrogram beamforming provides a robust detection algorithm for high-frequency signals at MJAR. The array aperture is large enough that f-k analysis performed on continuous AR-AIC functions, calculated from optimally bandpass-filtered signals at the different sites, can provide robust slowness estimates for regional P-waves. Given a significantly higher SNR for regional S-phases on the horizontal components of the 3-component site of MJAR, we would expect incoherent detection and estimation of S-phases to improve with 3-component sensors at all sites. Given the diversity of the IMS stations, and the diversity of the methods which provide optimal results for a given station, we advocate the development of seismic processing pipelines which can process highly heterogeneous inputs to help associate characteristics of the incoming signals with physical events.
Highlights
We define a seismic array to be a set of seismometers, distributed in a spatial pattern, with the distance between seismometer sites typically significantly shorter than the distance from source to receiver
The detection capability for the smallest seismic events in the region is determined by three primary International Monitoring System (IMS) seismic arrays: USRK (Ussuriysk, Russian Federation), KSRS (Wonju, South Korea), and MJAR (Matsushiro, Japan)
For the arrays USRK and KSRS, the slowness estimate for this regional signal is qualitatively identical for the two frequency bands; that is to say that we obtain a similar backazimuth and apparent velocity and the same identification of phase type
Summary
We define a seismic array to be a set of seismometers, distributed in a spatial pattern, with the distance between seismometer sites typically significantly shorter than the distance from source to receiver. The performance superiority comes both from the ability to improve the signal-to-noise ratio (SNR) through delay-and-stack beamforming and from the ability to obtain robust estimates for the backazimuth and slowness of a signal using spatial analysis of the arriving wavefront This helps the phase association process greatly by indicating both the likely identity of a seismic arrival and the direction it came from. The detection capability for the smallest seismic events in the region is determined by three primary IMS seismic arrays: USRK (Ussuriysk, Russian Federation), KSRS (Wonju, South Korea), and MJAR (Matsushiro, Japan) These three stations have very different geometries and signal coherence attributes; the IMS network in the region provides a useful laboratory for exploring the performance of processing algorithms. Could EMFP facilitate a more general form of seismic pipeline processing? We conclude with some perspectives for future development
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