This study compares the seismic performance of fixed-base and base-isolated structures for the KAI Boutique Hotel Building in Bandung, a region prone to earthquakes due to active faults such as the Lembang, and Baribis Faults. This study aims to analyze the differences in base shear, displacement, and inter-story drift between the two structural systems using response spectrum analysis, and evaluate the seismic performance level based on ATC-40 guidelines. The research methodology involved modeling an 11-story hotel building in ETABS v.18.1.0 with two scenarios: fixed-base and base- isolated models analyzed by response spectra. The base isolation system uses High Damping Rubber Bearings (HDRB). The main parameters analyzed include base shear, and inter-story deviation. The results show that base isolation significantly reduces base shear. For example, by response spectrum analysis, the base shear is reduced by 54.5% in the X direction and 56.3% in the Y direction compared to the fixed-base system. Base isolation effectively reduced the average inter-storey deviation by 68% in the X direction and 73% in the Y direction. Based on ATC-40, both fixed-base and base-isolated structures achieved the "Immediate Occupancy (IO)" performance level in all analyses, showing minimal structural and non-structural damage, allowing the building to continue functioning after the earthquake

Budiono, B., & Setiawan, A. (2014). Comparative Study of High-Damping Rubber Bearing and Friction Pendulum System Basic Isolation Systems in Reinforced Concrete Buildings. Journal of Civil Engineering, 21(3), 179. https://doi.org/10.5614/jts.2014.21.3.1

Chey, M. H., Chase, J. G., Mander, J. B., & Carr, A. J. (2013). Innovative seismic retrofitting strategy of added stories isolation system. Frontiers of Architecture and Civil Engineering in China, 7, 13-23. https://doi.org/10.1007/s11709-013-0195-9

Chopra, A. K. (2012). Dynamics of structures: theory and applications to earthquake engineering. In Choice Reviews Online (Vol. 33, Issue 02). https://doi.org/10.5860/choice.33- 0948

Kelly, J. M., & Konstantinidis, D. A. (2017). Mechanics of Rubber Bearings for Seismic and Vibration Isolation. Mechanics of Rubber Bearings for Seismic and Vibration Isolation, 2-. https://doi.org/10.1002/9781119971870

Makris, N. (2019). Seismic isolation: Early history. Earthquake Engineering and Structural Dynamics, 48(2), 269-283. https://doi.org/10.1002/eqe.3124

Meilano, I., Tiaratama, A. L., Wijaya, D. D., Maulida, P., Susilo, S., & Fitri, I. H. (2020). Analysis of Earthquake Potential in the South of Java Island Based on GPS Observations. Journal of Environment and Geological Disasters, 11(3), 151-159. https://doi.org/10.34126/jlbg.v11i3.352

Setio, H. D., Kusumastuti, D., Setio, S., Siregar, P. H. R., & Hartanto, A. (2012). Development of Seismic Isolation System for Building Structures Subjected to Earthquake Loads as a Solution to Limit Structural Response. Journal of Civil Engineering. https://doi.org/10.5614/jts.2012.19.1.1

SNI 1727:2020. (2020). Minimum design loads and related Criteria for buildings and other structures. Jakarta, 8, 1-336.

SNI 1726:2019. (2019). Application of Indonesian National Standard.

Vlachakis, G., Vlachaki, E., & Lourenço, P. B. (2020). Learning from failure: Damage and failure of masonry structures, after the 2017 Lesvos earthquake (Greece). Engineering Failure Analysis, 117(July), 104803. https://doi.org/10.1016/j.engfailanal.2020.104803