Citation: Paraskeva, T. S. & Kappos, A. J. (2010). Further development of a multimodal pushover analysis procedure for seismic assessment of bridges. Earthquake Engineering and Structural Dynamics, 39(2), pp. 211-222. doi: 10.1002/eqe.947 This is the accepted version of the paper.This version of the publication may differ from the final published version. SUMMARY An improvement is first suggested to the modal pushover analysis (MPA) procedure for bridges initially proposed by the writers [1], the key idea being that the deformed shape of the structure responding inelastically to the considered earthquake level is used in lieu of the elastic mode shape. The proposed MPA procedure is then verified by applying it to two actual bridges. The first structure is the Krystallopigi bridge, a 638m-long multi-span bridge, with significant curvature in plan, unequal pier heights, and different types of pier-to-deck connections. The second structure is a 100m-long three-span overpass bridge, typical in modern motorway construction in Europe, which, although ostensibly a regular structure, is found to exhibit a rather unsymmetric response in the transverse direction, mainly due to torsional irregularity. The bridges are assessed using response spectrum, 'standard' pushover (SPA), and modal pushover analysis, and finally using non-linear response history analysis (NL-RHA) for a number of spectrum-compatible motions. The MPA provided a good estimate of the maximum inelastic deck displacement for several earthquake intensities. The SPA on the other hand could not predict well the inelastic deck displacements along the bridge, because of the low contribution of the first mode to the total response of the bridge.
PermanentKEYWORDS: bridges, seismic assessment, pushover analysis, inelastic response, reinforced concrete, higher mode effects INTRODUCTION Extension of the 'standard', fundamental mode based, pushover analysis (SPA), to consider higher mode effects has attracted attention over the last decade. Several efforts made in this direction are briefly reviewed in a previous paper by Paraskeva et al. [1] wherein the Modal Pushover Analysis (MPA) proposed by Chopra and Goel [2] was extended to the case of bridges; the procedure was applied to a rather complex actual bridge, and results were compared with those from single-mode pushover and responsehistory analysis.
