Spatial variation of ground motion determined from accelerograms recorded on a highway bridge

SUMMARYLifeline systems have been heavily damaged during past earthquakes; this has often been attributed to the effect of differential ground motion at the supports of these long structures. Based on a stochastic model for the ground excitation the responses of pipelines and bridges of various span lengths subjected to either perfectly or partially correlated random input motions in the axial, lateral (i.e. transverse horizontal) and vertical directions are investigated and the significance of the spatial variation of ground motion is examined.

Lifeline response to spatially variable ground motions

Zerva

Ang

Wen

1988

Stiffness of non‐skew monolithic bridge abutments for seismic analysis

Wilson

1988

Self Cite

SUMMARY A simple analytic model is developed to describe the stiffness of non-skew monolithic highway bridge abutments for purposes of seismic bridge analysis. The model permits an evaluation of six equivalent discrete spring stiffnesses for three translational and three rotational degrees-of-freedom of the abutment and includes effects of the abutment walls, pile foundations and soil. These springs can be incorporated as boundary elements in a more detailed finiteelement analysis of the dynamic response of the bridge superstructure. A parametric study examines a range of abutment stiffnesses for 2,4 and 6 lane highway bridges. Application of the model to a single span bridge indicates the importance of including abutment stiffness in the determination of bridge frequencies and mode shapes in the transverse and vertical directions.

Response of indeterminate two‐span beam to spatially varying seismic excitation

Harichandran

Wang

1990

SUMMARYIn order to examine the effect of the spatial variation of ground motion on the response of an indeterminate structure, the stochastic responses of a two-span beam to spatially varying support excitations are analysed. A space-time earthquake ground motion model that accounts for both coherency decay and seismic wave propagation is used to specify the support motions, and the results are compared with those for various simplified excitations that are commonly used in practice. The response is computed through a linear random vibration approach with the structure being modelled by finite elements. The results of the study indicate that, even for moderate lengths, the effect of the spatial variation of ground motion can be significant. The assumption of fully coherent support motions (same excitations at all supports or delayed excitations allowing only for wave propagation) may be overconservative for some beams and unconservative for others.