Project Abstract

This project aims to investigate the seismic performance of high-rise buildings, a critical concern in regions prone to earthquakes. High-rise structures, with their unique architectural and structural features, pose distinct challenges in terms of withstanding the dynamic forces generated during seismic events. Understanding the response of these tall buildings to ground motion is essential for ensuring the safety of occupants and the resilience of urban infrastructure. The project will utilize advanced computational modeling and simulation techniques to assess the seismic behavior of high-rise buildings. This will involve the development of detailed finite element models that accurately capture the structural characteristics, material properties, and load-bearing mechanisms of the buildings. These models will then be subjected to a range of seismic ground motion scenarios, including historical earthquake records and synthetic accelerograms, to evaluate the building's response. A key aspect of the study will be the investigation of the influence of various design parameters on the seismic performance of high-rise buildings. This will include factors such as the building's height, structural system, foundation design, and the use of innovative damping and energy dissipation devices. The project will also explore the role of soil-structure interaction and its impact on the overall response of the building during seismic events. Through rigorous analyses, the project aims to provide valuable insights into the critical failure modes, displacement patterns, and stress distributions within high-rise structures under seismic loading. This information will be crucial in informing the development of improved design guidelines and code provisions for the construction of earthquake-resistant high-rise buildings. In addition to the computational modeling and simulation, the project will also incorporate experimental validation studies. Selected high-rise building models will be subjected to shake table testing or other experimental setups to verify the accuracy of the numerical predictions and to further enhance the understanding of the seismic response mechanisms. The findings of this project will have significant implications for the design and construction of high-rise buildings in seismic-prone regions. By providing a comprehensive understanding of the seismic performance of these structures, the project will contribute to the development of more resilient and safer urban environments. The knowledge gained from this study can also be leveraged to improve emergency response planning and disaster management strategies, ensuring the protection of lives and minimizing the economic and social disruptions caused by major earthquakes. Furthermore, the project will foster interdisciplinary collaboration among structural engineers, seismologists, and urban planners, promoting a holistic approach to addressing the challenges associated with high-rise buildings in seismic-active regions. The dissemination of the project's findings through publications, conferences, and stakeholder engagements will contribute to the advancement of the field and the shared knowledge within the broader engineering community. Overall, this project on the seismic performance evaluation of high-rise buildings represents a crucial step in enhancing the resilience and safety of urban infrastructure, ultimately contributing to the development of sustainable and disaster-resilient communities.

Project Overview