The effectiveness of mid-isolation systems in reducing the seismic demand of the superstructure above the isolation layer had been proved in many previous researches. It was also indicated, however, the response of substructure under the isolation layer may be enlarged due to the flexibility of the substructure and the contribution of the higher modes. On the contrary, the adoption of tuned mass damper (TMD) design can effectively control the dynamic response of the main structure (or substructure) induced by wind or seismic loads. Therefore, the concept of tuned mass damper system is incorporated into mid-story isolated design to control the seismic response of both superstructure and substructure, which is building mass damper (BMD) design. In BMD design, the superstructure above the isolation layer can serve as a tuned absorber mass whose stiffness and damping are provided by the isolation system composed of elastomeric bearings and additional dampers. Therefore, the advantages of conventional tuned mass damper and mid-story isolation systems can be integrated in the BMD design. This paper presents a shaking table test scheme, in order to verify the effectiveness of the BMD system with the design parameters deduced in the previous studies on the seismic protection of a building structure, the response of a series of specimens with optimum and non-optimum design parameters under different excitations had been measured. After the test, some system identification methods were performed to acquire the modal information such as frequency, damping ratio and modal participation mass ratio of test specimens. Based on the above information, numerical models which stimulate the test results can be established and the numerical analysis results and experimental results can be compared. Finally, in combination of the parameter analysis and experimental results, the behavior of BMD system and the influence of each parameters of interest on the seismic responses were realized. Also, the factors which caused errors in the experiment can be discussed and a modified optimal numerical model was proposed.