This study investigated the impact of soil-structure interaction on the seismic performance of masonry ancient pagodas. For this purpose, shaking table tests were conducted using a pagoda model to simulate the seismic damage patterns and damage evolution of the pagoda under conditions considering soil-structure interaction. Additionally, numerical models were established for both rigid foundation conditions and soil-structure interaction conditions, validated through dynamic characteristic testing and shaking table experiments. The results indicated that under soil-structure interaction conditions, the top of the pagoda cracked first, with severe damage occurring on the second floor. The damage characteristics of the pagoda differ significantly from those observed under rigid foundation conditions. The numerical simulations effectively predicted the dynamic response of the structure. Compared to the results obtained under rigid foundation conditions, the acceleration of the upper structure decreased by 34 %-79 % after considering soil-structure interaction, while the horizontal displacement at the top of the pagoda increased by 1.4 mm-7.8 mm. The inter-story displacement angle of the first floor was amplified by 3-10 times, with significant degradation of stiffness, while the impact on the stiffness of the top floor was relatively minor. The tensile damage to the pagoda was more pronounced, and the damage area shifted from the first floor to the second floor. The findings provide important references for the seismic assessment of masonry ancient pagodas.

来源平台：JOURNAL OF BUILDING ENGINEERING