Theoretical study of moving force identification on continuous bridges

A continuous bridge is modelled as a multi-span continuous Timoshenko beam with non-uniform cross-section. The vibration behaviour of this beam subjected to moving loads is analyzed by Hamilton's principle with the intermediate point constraints represented by very sti! linear springs. A method base

Force identi"cation from dynamic responses of bridges is an important inverse problem. The parameters of both the vehicle and the bridge play an important role in the force identi"cation. Based on the bending moments measured in the laboratory and the four identi"cation methods developed, this paper

Several methods have been developed recently to identify moving forces on a beam. The results from all of them exhibit #uctuations at the beginning and end of the time history and they are natural outcomes of the ill-conditioned inverse problem. Accuracy of the identi"ed forces also depends on the p

Identification of moving loads on bridges is an important inverse problem in the civil and structural engineering field. It is an effective way to better understand the interaction between the bridge and vehicles traversing it in order to achieve a satisfactory lifespan for the future bridge design.

This paper is concerned with liquid bridges between two spherical rigid bodies of equal radii under conditions where the effects of gravity are negligible. Previous work on the necessary condition for the stability of such bridges is examined and the minimum free-energy formulation applicable to any