Abstract
In low-to-moderate seismicity (intraplate) regions where locally recorded strong motion data are too scare for conventional regression analysis, stochastic simulations based on seismological modelling have often been used to predict ground motions of future earthquakes. This modelling methodology has been practised in Central and Eastern North America (CENA) for decades. It is cautioned that ground motion prediction equations (GMPE) that have been developed for use in CENA might not always be suited for use in another intraplate region because of differences in the crustal structure. This paper introduces a regionally adjustable GMPE, known as the component attenuation model (CAM), by which a diversity of crustal conditions can be covered in one model. Input parameters into CAM have been configured in the same manner as a seismological model, as both types of models are based on decoupling the spectral properties of earthquake ground motions into a generic source factor and a regionally specific path factor (including anelastic and geometric attenuation factors) along with a crustal factor. Unlike seismological modelling, CAM is essentially a GMPE that can be adapted readily for use in different regions (or different areas within a region) without the need of undertaking any stochastic simulations, providing that parameters characterising the crustal structure have been identified. In addressing the challenge of validating a GMPE for use in an area where instrumental data are scarce, modified Mercalli intensity (MMI) data inferred from peak ground velocity values predicted by CAM are compared with records of MMI of past earthquake events, as reported in historical archives. South-Eastern Australia (SEA) and South-Eastern China (SEC) are the two study regions used in this article for demonstrating the viability of CAM as a ground motion prediction tool in an intraplate environment.
Highlights
A ground motion prediction equation (GMPE) is a set of algebraic functions of earthquake magnitude, distance, and a site parameter, and may include parameters to identify the style of faulting [1,2,3,4,5]
In addressing the challenge of validating a GMPE for use in an area where instrumental data are scarce, modified Mercalli intensity (MMI) data inferred from peak ground velocity values predicted by component attenuation model (CAM) are compared with records of MMI of past earthquake events, as reported in historical archives
CAM was introduced as an engineering tool for providing realistic ground motion predictions for intraplate regions
Summary
A ground motion prediction equation (GMPE) is a set of algebraic functions of earthquake magnitude, distance, and a site parameter, and may include parameters to identify the style of faulting [1,2,3,4,5]. GMPEs are used to define the characteristics of ground motions for specific regions and earthquake scenarios (expressed in terms of magnitude-distance, or M-R combinations). In tectonically active regions (e.g., Western North America) where plenty of strong motion data can be captured by a network of densely distributed recording instruments, GMPEs are typically developed from regression analysis of recorded strong motion data. Empirical GMPEs, which were derived mainly from field recordings, should be capable of capturing regional specific earthquake ground motion characteristics [6,7]. Empirical GMPEs may give results that are very sensitive to data from isolated records and the type of regression techniques adopted, and more so when data are scarce [8].
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