Recent research on identification of moving loads on bridges

Assumed mode shapes are often used to determine the responses of a bridge deck under the passage of moving loads. However, the use of these mode shapes in the inverse problem of force identi"cation would lead to unnecessary errors due to their inherent inaccuracy. Direct di!erentiation of the measur

A method to identify moving forces on a continuous bridge has been developed in this paper. The bridge is modelled as a Bernoulli–Euler beam and the boundary value problem of the beam is solved to get the exact mode shape functions of the vibrating beam with intermediate supports. As the number of s

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

The dynamic loading on a multi-lane continuous bridge deck due to vehicles moving on top at a constant velocity is investigated. The bridge is modelled as a multi-span continuous orthotropic rectangular plate with line rigid intermediate supports. The vehicle is simulated as a two-axle three-dimensi

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