The deformation of existing bridges under external loads is a critical parameter reflecting the structural load-bearing capacity. Bridgeload tests typically require the load to reach a specified loadefficiencyratioto obtain structural linear state and potential nonlinear state. Dynamic load testing serves as an efficient and economical method for obtaining load-deformation relationships of structures. However, conventional bridge dynamic tests are usually based on linear assumptions and are unable to assess structural nonlinear state under the goal load. This paper proposes a multi-level dynamic loading test theoretical framework for evaluating bridge bearing capacity. The proposed method utilizes structural quasi-linear responses under low loadefficiencyratio to identify dynamic characteristic parameters and assess stiffness degradation states, whilethe potentially nonlinear response of the structure underthe high loadefficiencyratio is utilized to evaluate resistance degradation state. The study reveals the impacts of structural parameter change and strain rate effect on multi-level dynamic testing. Accordingly, anexcitation amplitude adjustment method considering these two factors is derived. Compared with traditional dynamic testing, the proposed approach enables more comprehensive bridge service state evaluation without compromising testing efficiency. The effectiveness of the method is validated through a numerical example of a simply supported beamand anexperimental example of a T-shaped continuous girder bridg
Xue et al. (Fri,) studied this question.
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