Shear performance of AAC masonry triplets strengthened by reinforcing steel wire mesh in the bed and bed-head joint Richard Badonbok Lyngkhoi, Teiborlang Warjri and Comingstarful Marthong
Abstract; Full Text (2023K) .	pages 149-160.	DOI: 10.12989/eas.2023.25.3.149

Abstract
Over the course of the last 4-5 years, India's northeastern region have widely used Autoclaved Aerated Concrete (AAC) blocks to construct load-bearing masonry structures. The aim of this investigation is to examine the shear characteristics of AAC masonry triplet assemblage strengthened by using two techniques, i.e., the bead joint (BJ) and the bed-head joint (BHJ) technique. Three unique variations of wire mesh were involved in the strengthening method. Furthermore, three strengthening configurations were used to strengthen each of the three wire mesh variations and the two-strengthening method, i.e. (-), L and (Z) configuration. The unreinforced and reinforced triplet masonry wallets were tested under direct shear test. From the results obtained, the 'BJ' triplet masonry wallets observed an enhanced in shear strength of about 2.23% to 23.33 % whereas the 'BHJ' triplet masonry wallets observed an enhanced in shear strength of about 22.92% to 50.69%. The "BHJ" strengthening method effectively enhance the shear strength of the triplet masonry wallets compared to the "BJ" and the "UR" wallets with an increase in capacity as the wire mesh strength increases. Furthermore, in terms of the strengthening configuration, the (Z) configuration performs better, followed by the (L) and (-) configuration demonstrating the strengthening configuration effectiveness.

Key Words
AAC blocks; bed-head joint; bed joint; masonry walls; steel wire mesh; strengthening; triplet test

Address
Department of Civil Engineering, National Institute of Technology Meghalaya, Shillong 793003, India

Dynamic loading tests and analytical modeling for high-damping rubber bearings Kyeonghoon Park, Taiji Mazda and Yukihide Kajita
Abstract; Full Text (3083K) .	pages 161-175.	DOI: 10.12989/eas.2023.25.3.161

Abstract
High-damping rubber bearings (HDRB) are commonly used as seismic isolation devices to protect civil engineering structures from earthquakes. However, the nonlinear hysteresis characteristics of the HDRB, such as their dependence on material properties and hardening phenomena, make predicting their behavior during earthquakes difficult. This study proposes a hysteretic model that can accurately predicts the behavior of shear deformation considering the nonlinearity when designing the seismic isolation structures using HDR bearings. To model the hysteretic characteristics of the HDR, dynamic loading tests were performed by applying sinusoidal and random waves on scaled-down specimens. The test results show that the nonlinear characteristics of the HDR strongly correlate with the shear strain experienced in the past. Furthermore, when shear deformation occurred above a certain level, the hardening phenomenon, wherein the stiffness increased rapidly, was confirmed. Based on the experimental results, the dynamic characteristics of the HDR, equivalent stiffness, equivalent damping ratio, and strain energy were quantitatively evaluated and analyzed. In this study, an improved bilinear HDR model that can reproduce the dependence on shear deformation and hardening phenomena was developed. Additionally, by proposing an objective parameter-setting procedure based on the experimental results, the model was devised such that similar parameters could be set by anyone. Further, an actual dynamic analysis could be performed by modeling with minimal parameters. The proposed model corresponded with the experimental results and successfully reproduced the mechanical characteristics evaluated from experimental results within an error margin of 10%.

Key Words
base isolation; dampers; dynamic analysis; energy dissipation; high-damping rubber; hysteresis model

Address
Department of Civil Engineering, Kyushu University, 744 Motooka Nishi-ku Fukuoka, Japan

Enhanced macro element for nonlinear analysis of masonry infilled RC frame structures Mebarek Khelfi and Fouad Kehila
Abstract; Full Text (1656K) .	pages 177-186.	DOI: 10.12989/eas.2023.25.3.177

Abstract
Reinforced concrete frames with a masonry infill panel is a structural typology frequently used worldwide. In seismic cases, the interaction between the masonry infill and the RC frames constitutes one of the most complex subjects in earthquake engineering. In this work, an enhancement of an existing numerical model is proposed to improve the estimation of lateral strength and stiffness of masonry-infilled frame structures and predict their probable failure modes. The proposed improvement is based on attributing corrective coefficients to the shear strength of each diagonal shear spring of the macro element, which simulates the masonry infill. The improved numerical model is validated by comparing the results with those of the original numerical model and with experimental results available in the literature. The enhanced macro element model can be used as a powerful, accessible tool for assessing the capacity and stiffness of masonry-infilled frame structures and predicting their probable failure modes.

Key Words
corrective coefficients; enhanced macro element model; failure mode; masonry infilled reinforced concrete frame structure

Address
Department of Civil Engineering, National Earthquake Engineering Research Center CGS 01 Rue Kaddour RAHIM, BP 252, Hussein Dey, Algiers, Algeria

Development of a predictive functional control approach for steel building structure under earthquake excitations Mohsen Azizpour, Reza Raoufi and Ehsan Kazeminezhad
Abstract; Full Text (3761K) .	pages 187-198.	DOI: 10.12989/eas.2023.25.3.187

Abstract
Model Predictive Control (MPC) is an advanced control approach that uses the current states of the system model to predict its future behavior. In this article, according to the seismic dynamics of structural systems, the Predictive Functional Control (PFC) method is used to solve the control problem. Although conventional PFC is an efficient control method, its performance may be impaired due to problems such as uncertainty in the structure of state sensors and process equations, as well as actuator saturation. Therefore, it requires the utilization of appropriate estimation algorithms in order to accurately evaluate responses and implement actuator saturation. Accordingly, an extended PFC is presented based on the H-ifinity (Hoo) filter (HPFC) while considering simultaneously the saturation actuator. Accordingly, an extended PFC is presented based on the Hifinity (Hoo) filter (HPFC) while considering the saturation actuator. Thus, the structural responses are formulated by two estimation models using the Hoo filter. First, the Hoo filter estimates responses using a performance bound (0). Second, the Hoo filter is converted into a Kalman filter in a special case by considering the 0 equal to zero. Therefore, the scheme based on the Kalman filter (KPFC) is considered a comparative model. The proposed method is evaluated through numerical studies on a building equipped with an Active Tuned Mass Damper (ATMD) under near and far-field earthquakes. Finally, HPFC is compared with classical (CPFC) and comparative (KPFC) schemes. The results show that HPFC has an acceptable efficiency in boosting the accuracy of CPFC and KPFC approaches under earthquakes, as well as maintaining a descending trend in structural responses.

Key Words
active mass damper; actuator saturation; H-infinity filter; predictive functional control; seismic excitation

Address
Department of Civil Engineering, Ahvaz Branch, Islamic Azad University, Ahvaz, Iran

Evaluation of EC8 and TBEC design response spectra applied at a region in Turkey Yusuf Guzel and Fidan Guzel
Abstract; Full Text (2175K) .	pages 199-208.	DOI: 10.12989/eas.2023.25.3.199

Abstract
Seismic performance analysis is one of the fundamental steps in the design of new or retrofitting buildings. In the seismic performance analysis, the adapted spectral acceleration curve for a given site mainly governs the seismic behavior of buildings. Since every soil site (class) has a different impact on the spectral accelerations of input motions, different spectral acceleration curves have to be involved for every soil class that the building is located on top of. Modern seismic design codes (e.g., Eurocode 8, EC8, or Turkish Building Earthquake Code, TBEC) provide design response spectra for all the soil classes to be used in the building design or retrofitting. This research aims to evaluate the EC8 and TBEC based design response spectra using the spectra of real earthquake input motions that occurred (and were recorded at only soil classes A, B and C, no recording is available at soil class D) in a specific area in Turkey. It also conducts response spectrum analyses of 5, 10 and 13 floor reinforced concrete building models under EC8, TBEC and actual spectral response curves. The results indicate that the EC8 and especially TBEC given design response spectra cannot be able to represent the mean actual spectral acceleration curves at soil classes A, B and C. This is particularly observed at periods higher than 0.3 s, 0.42 s and 0.55 s for the TBEC design response spectra, 0.54 s, 0.65 s and 0.84 s for the EC8 design response spectra at soil classes A, B and C, respectively. This is also reflected to the shear forces of three building models, as actual spectral acceleration curves lead to the highest shear forces, followed by the shear forces obtained from EC8 and, then, the TBEC design response spectra.

Key Words
design response spectra; input motion recordings; seismic design codes; seismic performance analysis; soil classes

Address
Yusuf Guzel: Department of Civil Engineering, Faculty of Engineering, Necmettin Erbakan University, Konya, Turkey
Fidan Guzel: Department of Civil Engineering, Faculty of Engineering, Igdir University, Igdir, Turkey

Damage evaluation of masonry buildings during Kahramanmaraş (Türkiye) earthquakes on February 06, 2023 Ercan Işik, Aydin Büyüksaraç, Fatih Avcil, Enes Arkan, M.Cihan Ayd
Abstract; Full Text (2389K) .	pages 209-221.	DOI: 10.12989/eas.2023.25.3.209

Abstract
The Mw=7.7 (Pazarcik-Kahramanmaraş) and Mw=7.6 (Elbistan-Kahramanmaraş) earthquakes that occurred in Türkiye on 06.02.2023 with 9 hours' intervals, caused great losses of life and property as the biggest catastrophe in the instrumental period. The earthquakes affecting an area of 14% of the country were enormous and caused a great deal of loss of life and damage. Numerous buildings have collapsed or damaged at different levels, both in the city centers and in rural areas. Within the scope of this study, masonry structure damage built from different types of materials in the earthquake region was taken into consideration. In this study, the damage and causes of such masonry structures that do not generally receive engineering services were examined and explained in detail. Insufficient interlocking between wall-wall and wall-roof, inadequate masonry, lack of horizontal and vertical bond beams, usage of low-strength materials, poor workmanship, and heavy earthen roof are commonly caused to structural damages. Separation at the corner point and out-of-plane mechanism in structural walls, and heavy earthen roof damages are common types of damage in masonry structures.

Key Words
damage; Kahramanmaraş earthquakes; masonry structures; Türkiye

Address
Ercan Işik, Fatih Avcil, Enes Arkan, M.Cihan Aydin and Ali Emre Ulu: Department of Civil Engineering, Bitlis Eren University, TR-13000, Bitlis, Türkiye
Aydin Büyüksaraç: Çan Vocational School, Çanakkale Onsekizmart University, TR-17100, Çanakkale, Türkiye