Optimization of base-isolated structure with negative stiffness tuned inerter damper targeting seismic response reduction Jean Paul Irakoze, Shujin Li, Wuchuan Pu, Patrice Nyangi and Amédée Sibomana
Abstract; Full Text (3476K) .	pages 399-415.	DOI: 10.12989/eas.2023.25.6.399

Abstract
In this study, we investigate the use of a negative stiffness tuned inerter damper system to improve the performance of a base-isolated structure. The negative stiffness tuned inerter damper system consists of a tuned inerter damper connected in parallel with a negative stiffness element. To find the optimal parameters for the base-isolated structure with negative stiffness tuned inerter damper system, we develop an optimization method based on performance criteria. The objective of the optimization is to minimize the superstructure acceleration response ratio, while ensuring that the base displacement response ratio remains below a specified target value. We evaluate the proposed method by conducting numerical analyses on an eight-story building. The structure is modeled using both a simplified 3-degree-of-freedom system and a more detailed story-by-story shear-beam model. Lastly, a comparative analysis using time history analysis is performed to compare the performance of the base-isolated structure with negative stiffness tuned inerter damper system with that of the base-isolated structure and base-isolated structure with tuned inerter damper systems. The results obtained from the comparative analysis show that the negative stiffness tuned inerter damper system outperforms the tuned inerter damper system in reducing the dynamic seismic response of the base-isolated structure. Overall, this study demonstrates that the negative stiffness tuned inerter damper system can effectively enhance the performance of base-isolated structures, providing improved seismic response reduction compared to other systems.

Key Words
base-isolated structure; negative stiffness; optimization; seismic response; tuned inerter damper

Address
Jean Paul Irakoze, Shujin Li, Wuchuan Pu and Amédée Sibomana: School of Civil Engineering and Architecture, Wuhan University of Technology, Wuhan 430070, China
Patrice Nyangi: Civil Engineering Department, Mbeya University of Science and Technology, Tanzania

Extending torsional balance concept for one and two way asymmetric structures with viscous dampers Amir Shahmohammadian, Mohammad Reza Mansoori, Mir Hamid Hosseini and Negar Lotfabadi Bidgoli
Abstract; Full Text (1859K) .	pages 417-427.	DOI: 10.12989/eas.2023.25.6.417

Abstract
If the center of mass and center of stiffness or strength of a structure plan do not coincide, the structure is considered asymmetric. During an earthquake, in addition to lateral vibration, the structure experiences torsional vibration as well. Lateraltorsional coupling in asymmetric structures in the plan will increase lateral displacement at the ends of the structure plan and, as a result, uneven deformation demand in seismically resistant frames. The demand for displacement in resistant frames depends on the magnitude of transitional displacement to rotational displacement in the plan and the correlation between these two. With regard to the inability to eliminate the asymmetrical condition due to various reasons, such as architectural issues, this study has attempted to use supplemental viscous dampers to decrease the correlation between lateral and torsional acceleration or displacement in the plan. This results in an almost even demand for lateral deformation and acceleration of seismic resistant frames. On this basis, using the concept of Torsional Balance, adequate distribution of viscous dampers for the decrease of this correlation was determined by transferring the "Empirical Center of Balance" (ECB) to the geometrical center of the structure plan and thus obtaining an equal mean square value of displacement and acceleration of the plan edges. This study analyzed stiff and flexible torsional structures with one-way and two-way mass asymmetry in the Opensees software. By implementing the Particle Swarm Optimization (PSO) algorithm, the optimum formation of dampers for controlling lateral displacement and acceleration is determined. The results indicate that with the appropriate distribution of viscous dampers, not only does the lateral displacement and acceleration of structure edges decrease but the lateral displacement or acceleration of the structure edges also become equal. It is also observed that the optimized center of viscous dampers for control of displacement and acceleration of structure depends on the amount of mass eccentricity, the ratio of uncoupled torsional-to-lateral frequency, and the amount of supplemental damping ratio. Accordingly, distributions of viscous dampers in the structure plan are presented to control the structure's torsion based on the parameters mentioned.

Key Words
asymmetric structures; mass eccentricity; particle swarm optimization; torsion; torsional balance

Address
Amir Shahmohammadian, Mohammad Reza Mansoori and Mir Hamid Hosseini: Department of Civil Engineering, Science and Research Branch, Islamic Azad University, shodada Hesarak blvd, Daneshgah Square,Sattari Highway,Tehran, I.R. IRAN
Negar Lotfabadi Bidgoli: Department of Civil Engineering, Central of Tehran Branch, Islamic Azad University, Chahar Bagh blvd, Punak Square, Ashrafi Esfahani Highway, Tehran, I.R. IRAN

Seismic damage vulnerability of empirical composite material structure of adobe and timber Si-Qi Li
Abstract; Full Text (3224K) .	pages 429-442.	DOI: 10.12989/eas.2023.25.6.429

Abstract
To study the seismic vulnerability of the composite material structure of adobe and timber, we collected and statistically analysed empirical observation samples of 542,214,937 m2 and 467,177 buildings that were significantly impacted during the 179 earthquakes that occurred in mainland China from 1976 to 2010. In multi-intensity regions, combined with numerical analysis and a probability model, a non-linear continuous regression model of the vulnerability, considering the empirical seismic damage area (number of buildings) and the ratio of seismic damage, was established. Moreover, a probability matrix model of the empirical seismic damage mean value was provided. Considering the coupling effect of the annual and seismic fortification factors, an empirical seismic vulnerability curve model was constructed in the multiple-intensity regions. A probability matrix model of the mean vulnerability index (MVI) was proposed, and was validated through the above-mentioned reconnaissance sample data. A matrix model of the MVI of the regions (19 provinces in mainland China) based on the parameter (MVI) was established.

Key Words
composite material structure of adobe and timber; empirical seismic damage reconnaissance; mean vulnerability index matrix model; non-linear continuous regression model of vulnerability; seismic vulnerability analysis

Address
School of Civil Engineering, Heilongjiang University, No.74, Xuefu Road, Harbin City, China

Seismic behavior of RC frames with partially attached steel shear walls: A numerical study Kambiz Cheraghi, Majid Darbandkohi, Mehrzad TahamouliRoudsari and Sasan Kiasat
Abstract; Full Text (2646K) .	pages 443-454.	DOI: 10.12989/eas.2023.25.6.443

Abstract
Steel shear walls are used to strengthen steel and concrete structures. One such system is Partial Attached Steel Shear Walls (PASSW), which are only connected to frame beams. This system offers both structural and architectural advantages. This study first calibrated the numerical model of RC frames with and without PASSW using an experimental sample. The seismic performance of the RC frame was evaluated by 30 non-linear static analyses, which considered stiffness, ductility, lateral strength, and energy dissipation, to investigate the effect of PASSW width and column axial load. Based on numerical results and a curve fitting technique, a lateral stiffness equation was developed for frames equipped with PASSW. The effect of the shear wall location on the concrete frame was evaluated through eight analyses. Nonlinear dynamic analysis was performed to investigate the effect of the shear wall on maximum frame displacement using three earthquake records. The results revealed that if PASSW is designed with appropriate stiffness, it can increase the energy dissipation and ductility of the frame by 2 and 1.2 times, respectively. The stiffness and strength of the frame are greatly influenced by PASSW, while axial force has the most significant negative impact on energy dissipation. Furthermore, the location of PASSW does not affect the frame's behavior, and it is possible to have large openings in the frame bay.

Key Words
concrete/reinforced concrete; numerical simulation; push over analysis; retrofit/repair; strengthening

Address
Kambiz Cheraghi: Department of Civil Engineering, Razi University, Kermanshah, Iran
Majid Darbandkohi and Mehrzad TahamouliRoudsari: Department of Civil Engineering, Azad University, Kermanshah, Iran
Sasan Kiasat: Department of Civil and Environmental Engineering, AmirKabir University, Tehran, Iran

Seismic response control of irregular asymmetric structure with voided slabs by distributed tuned rotary mass damper devices Shujin Li, Irakoze Jean Paula and Ling Mao
Abstract; Full Text (1838K) .	pages 455-467.	DOI: 10.12989/eas.2023.25.6.455

Abstract
This study focuses on demonstrating the effectiveness of vibration control of tuned rotary mass damper (TRMD) for reducing the bidirectional and torsional response of the irregular asymmetric structure with voided slabs under earthquake excitations. The TRMD arranged in plane of one-story eccentric structure is proposed as a distributed tuned rotary mass damper (DTRMD) system. Lagrange's equation is used to derive the equations of motion of the controlled system. The optimum position and number of TRMD are numerically investigated under harmonic excitation and the control effects of different distributions are discussed. Furthermore, a shaking table test is conducted under different excitation cases, including free vibration, forced vibration and seismic wave to investigate the absorption performance of the device. The numerical simulations of different distributions of the TRMDs show that the DTRMDs are more effective in reduction of the displacement response of the asymmetric structure under the same mass ratio, even when the degree of eccentricity becomes large. However, with small degree of eccentricity, the unreasonable asymmetrical arrangement may cause the increase of the peak value of the rotational angular displacement. Finally, the experimental investigations exhibit similar results of translational displacement of the structure. It is concluded that the vibration of the irregular asymmetric structure can be controlled more economically and effectively by reducing the mass ratio through reducing the quantity of TRMDs at the high stiffness end.

Key Words
distributed tuned rotary mass damper; irregular structure; response analysis; shake table test; vibration control

Address
School of Civil Engineering and Architecture, Wuhan University of Technology, Wuhan 430070, China

Utilization of deep learning-based metamodel for probabilistic seismic damage analysis of railway bridges considering the geometric variation Xi Song, Chunhee Cho and Joonam Park
Abstract; Full Text (1579K) .	pages 469-479.	DOI: 10.12989/eas.2023.25.6.469

Abstract
A probabilistic seismic damage analysis is an essential procedure to identify seismically vulnerable structures, prioritize the seismic retrofit, and ultimately minimize the overall seismic risk. To assess the seismic risk of multiple structures within a region, a large number of nonlinear time-history structural analyses must be conducted and studied. As a result, each assessment requires high computing resources. To overcome this limitation, we explore a deep learning-based metamodel to enable the prediction of the mean and the standard deviation of the seismic damage distribution of track-on steel-plate girder railway bridges in Korea considering the geometric variation. For machine learning training, nonlinear dynamic time-history analyses are performed to generate 800 high-fidelity datasets on the seismic response. Through intensive trial and error, the study is concentrated on developing an optimal machine learning architecture with the pre-identified variables of the physical configuration of the bridge. Additionally, the prediction performance of the proposed method is compared with a previous, welldefined, response surface model. Finally, the statistical testing results indicate that the overall performance of the deep-learning model is improved compared to the response surface model, as its errors are reduced by as much as 61%. In conclusion, the model proposed in this study can be effectively deployed for the seismic fragility and risk assessment of a region with a large number of structures.

Key Words
deep learning; geometric variation; metamodel; railway bridge; response surface; seismic risk

Address
Xi Song: Department of Civil and Architectural Engineering & Construction Management, Milwaukee School of Engineering, Milwaukee, WI 53202, United States
Chunhee Cho: Department of Civil and Environmental Engineering, University of Hawaii at Manoa, Honolulu, HI 96822, United States
Joonam Park: Department of Civil and Environmental Engineering, Wonkwang University, Iksan, Jeollabuk-do, 54538, Korea