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CONTENTS | |
Volume 33, Number 5, May 2024 |
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- Carbonation depth prediction of concrete bridges based on long short-term memory Youn Sang Cho, Man Sung Kang, Hyun Jun Jung and Yun-Kyu An
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Abstract; Full Text (1714K) . | pages 325-332. | DOI: 10.12989/sss.2024.33.5.325 |
Abstract
This study proposes a novel long short-term memory (LSTM)-based approach for predicting carbonation depth, with the aim of enhancing the durability evaluation of concrete structures. Conventional carbonation depth prediction relies on statistical methodologies using carbonation influencing factors and in-situ carbonation depth data. However, applying in-situ data for predictive modeling faces challenges due to the lack of time-series data. To address this limitation, an LSTM-based carbonation depth prediction technique is proposed. First, training data are generated through random sampling from the distribution of carbonation velocity coefficients, which are calculated from in-situ carbonation depth data. Subsequently, a Bayesian theorem is applied to tailor the training data for each target bridge, which are depending on surrounding environmental conditions. Ultimately, the LSTM model predicts the time-dependent carbonation depth data for the target bridge. To examine the feasibility of this technique, a carbonation depth dataset from 3,960 in-situ bridges was used for training, and untrained timeseries data from the Miho River bridge in the Republic of Korea were used for experimental validation. The results of the experimental validation demonstrate a significant reduction in prediction error from 8.19% to 1.75% compared with the conventional statistical method. Furthermore, the LSTM prediction result can be enhanced by sequentially updating the LSTM model using actual time-series measurement data.
Key Words
bridge; concrete carbonation; deep learning; long short-term memory; prediction; time-series update
Address
(1) Youn Sang Cho, Man Sung Kang, Yun-Kyu An:
Department of Architectural Engineering, Sejong University 209 Neungdong-ro, Gwangjin-gu, Seoul, Republic of Korea;
(2) Hyun Jun Jung:
Korea Authority of Land & Infrastructure Safety (KALIS), Jinju 52856, Republic of Korea.
- Deflection aware smart structures by artificial intelligence algorithm Qingyun Gao, Yun Wang, Zhimin Zhou and Khalid A. Alnowibet
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Abstract; Full Text (1798K) . | pages 335-347. | DOI: 10.12989/sss.2024.33.5.335 |
Abstract
There has been an increasing interest in the construction of smart buildings that can actively monitor and react to their surroundings. The capacity of these intelligent structures to precisely predict and respond to deflection is a crucial feature that guarantees both their structural soundness and efficiency. Conventional techniques for determining deflection often depend on intricate mathematical models and computational simulations, which may be time- and resource-consuming. Artificial intelligence (AI) algorithms have become a potent tool for anticipating and controlling deflection in intelligent structures in response to these difficulties. The term "deflection-aware smart structures" in this sense refers to constructions that have AI algorithms installed that continually monitor and analyses deflection data in order to proactively detect any problems and take appropriate action. These structures anticipate deflection across a range of operating circumstances and environmental factors by using cutting-edge AI approaches including deep learning, reinforcement learning, and neural networks. AI systems are able to predict real-time deflection with high accuracy by using data from embedded sensors and actuators. This capability enables the systems to identify intricate patterns and linkages. Intelligent buildings have the potential to self-correct in order to reduce deflection and maximize performance. In conclusion, the development of deflection-aware smart structures is a major stride forward for structural engineering and has enormous potential to enhance the performance, safety, and dependability of designed systems in a variety of industries.
Key Words
applied voltage; artificial intelligence algorithm; DQA; HDQM; piezoelectric materials
Address
(1) Qingyun Gao, Yun Wang, Zhimin Zhou:
FAIR FRIEND Institute of Intelligent Manufacturing, Hangzhou Vocational & Technical College, Hangzhou 310018, China;
(2) Khalid A. Alnowibet:
Statistics and Operations Research Department, College of Science, King Saud University, Riyadh, 11451, Saudi Arabia.
- Loop closure-based high-resolution façade digital modeling technique of large-scale dams using UAV Myung Soo Kang, Keunyoung Jang, Yong-Rae Yu and Yun-Kyu An
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Abstract; Full Text (4849K) . | pages 349-358. | DOI: 10.12989/sss.2024.33.5.349 |
Abstract
Structural digital models can be effectively established by spatially obtaining digital images using an unmanned aerial vehicle (UAV). One of the main purposes of the structural digital modeling is computer vision-based exterior damage detection of a target structure. To investigate micro-scale damage from the digital model, high-resolution digital images obtained with a close-up vision survey is typically required. However, serial image synthesis such as image stitching may cumulate stitching errors as the number of scanned images increases. Therefore, in this paper, a novel loop closure-based digital image stitching technique is proposed and experimentally validated using the close-up surveyed digital images acquired from an in-situ dam structure located in South Korea. The test results reveal that the proposed technique outperforms a non-loop closure-based image stitching technique, which can cause serious distortions, such as ghosting and vanishing phenomena.
Key Words
close-up UAV surveying; computer vision; dam; digital image stitching; loop closure; structural façade digital model
Address
(1) Myung Soo Kang, Keunyoung Jang, Yun-Kyu An:
Department of Architectural Engineering, Sejong University, 209 Neungdong-ro, Gwangjin-gu, Seoul 05006, Republic of Korea;
(2) Yong-Rae Yu:
Department of Civil and Environmental Engineering, Sejong University, 209 Neungdong-ro, Gwangjin-gu, Seoul 05006, Republic of Korea.
- Computing of output of piezoelectric actuator under voltage excitation Yongfeng Fang, Kong Fah Tee and Yong Yan
open access | ||
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Abstract; Full Text (1108K) . | pages 359-364. | DOI: 10.12989/sss.2024.33.5.359 |
Abstract
It is difficult to calculate the output force of a single-layer piezoelectric actuator under voltage excitation. In this paper, the piezoelectric actuator is organically combined with the mass-spring-damping system, and the deformation of the piezoelectric actuator under voltage excitation is transformed into the displacement of the mass-spring-damping system. Then, according to the differential equation of the system, the formulae of the mechanical output of the piezoelectric actuator under sinusoidal alternating current and DC step excitation are obtained by using the Laplace change and the inverse change, respectively. Finally, the proposed equations are verified by using ceramic piezoelectric actuators and PVDF actuators, respectively. The results are compared with the existing ones, which shows that the proposed method is feasible, easy, and practical.
Key Words
actuator; damping; output force; piezoelectric; voltage excitation
Address
(1) Yongfeng Fang, Yong Yan:
Ningxia Normal University, School of Physics and Electric Information, Guyuan 756000, China;
(2) Kong Fah Tee:
Department of Civil and Environmental Engineering, King Fahd University of Petroleum and Minerals, Dhahran 31261, Saudi Arabia;
(3) Kong Fah Tee:
Interdisciplinary Research Center for Construction and Building Materials, KFUPM, Dhahran 31261, Saudi Arabia.
- Intelligent optimal grey evolutionary algorithm for structural control and analysis Z.Y. Chen, Yahui Meng, Ruei-Yuan Wang and Timothy Chen
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Abstract; Full Text (1445K) . | pages 365-374. | DOI: 10.12989/sss.2024.33.5.365 |
Abstract
This paper adopts a new approach in which nonlinear vibrations can be controlled using fuzzy controllers by optimal grey evolutionary algorithm. If the fuzzy controller cannot stabilize the systems, then the high frequency is injected into the system to assist the controller, and the system is asymptotically stabilized by adjusting the parameters. This paper uses the GM (grey model) and the neural network prediction model. The structure of the neural network is improved from a single factor, and multiple data inputs are extended to various factors and numerous data inputs. The improved model expands the applicable range of uncontrolled elements and improves the accuracy of controlled prediction, using the model that has been trained and stabilized by multiple learning. The simulation results show that the improved gray neural network model has higher prediction accuracy and reliability than the traditional GM model, improving controlled management and pre-control ability. In the combined prediction, the time series parameters and the predicted values obtained from the GM (1,1) (Grey Model of first order and one variable) are simultaneously used as the input terms of the neural network, considering the influence of the non-equal spacing of the data, which makes the results of the combined gray neural network model more rationalized. By adjusting the model structure and system parameters to simulate and analyze the controlled elements, the corresponding risk change trend graphs and prediction numerical calculation results are obtained, which also realize the effective prediction of controlled elements. According to the controlled warning principle and objective, the fuzzy evaluation method establishes the corresponding early warning response method. The goals of this paper are towards access to adequate, safe and affordable housing and basic services, promotion of inclusive and sustainable urbanization and participation, implementation of sustainable and disaster-resilient buildings, sustainable human settlement planning and manage.
Key Words
composite structures; energy equations; intelligent control function; structural control; tuned mass damper
Address
(1) Z.Y. Chen, Yahui Meng, Ruei-Yuan Wang:
School of Science, Guangdong University of Petrochemical Technology, Maoming 525000, Guangdong, China;
(2) Timothy Chen:
California Institute of Technology, Pasadena, CA 91125, USA.
- Real-time estimation of responses and loads of real-scale pipes subjected to earthquakes and external loads using digital twin technology Dongchang Kim, Shinyoung Kwag, Sung-Jin Chang and Seunghyun Eem
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Abstract; Full Text (2997K) . | pages 375-383. | DOI: 10.12989/sss.2024.33.5.375 |
Abstract
Infrastructure facilities contain various pipe systems, which can be considerably damaged by external loads such as earthquakes. Therefore, structural health monitoring (SHM) and safety assessment of pipes are crucial. Digital twin technology for SHM of pipes is important in the industry. This study proposes a digital twin system that estimates the behavior, stress, and external load of real-scale pipes in real time under simultaneous seismic and external loads using a minimum number of sensors. Vibration tests were performed to construct the digital twin system, and a numerical model was developed that considered the dynamic characteristics of a target pipe. Moreover, a reduced-order modeling technique of a numerical model was applied to enhance its real-time performance. The digital twin system successfully estimated the response of the pipe at all points. Verification of the digital twin system was performed by comparing it with the experimental parameters of a real-scale pipe. The proposed digital twin system can help enhance SHM and system's maintenance.
Key Words
digital twin; pipe system; real time; reduced-order modeling; structural health monitoring
Address
(1) Dongchang Kim, Seunghyun Eem:
School of Convergence & Fusion System Engineering, Kyungpook National University, 80 Daehak-ro, Daegu, 41566, Republic of Korea;
(2) Shinyoung Kwag:
Department of Civil and Environmental Engineering, Hanbat National University, 125 Dongseo-daero, Daejeon, 34158, Republic of Korea;
(3) Sung-Jin Chang:
Seismic Research and Test Center, Pusan National University, 49 Busandaehak-ro, Yangsan, 50612, Republic of Korea.